Carcinoembryonic antigen cell adhesion molecule 1 (CEACAM1) structure and uses thereof in drug identification and screening

ABSTRACT

Disclosed is the first crystal structure in the carcinoembryonic antigen (CEA) family, the mouse CEACAM1a[1,4], containing the N-terminal functional domain that is characterized as having a uniquely folded CC′ loop. This novel feature could not be predicted based on sequence analysis alone. The structure has provided a prototypic architecture for modeling human homologues within the CEA family. These tertiary structures are used in a number of screening methods for identifying candidate molecules that have a binding affinity for the tertiary structure of the CC′ loop and its vicinity. Pharmaceutical preparations that include one or more of such identified candidates may then be provided and used in treatments for certain bacterial and viral infections, certain tumors and disorders of angiogenesis or immune responses and autoimmune disease.

RELATED APPLICATIONS

[0001] This present invention claims priority to U.S. application Ser.No. 10/118,471 filed Apr. 5, 2002.

GOVERNMENT LICENSE RIGHTS

[0002] The United States Government may own rights to the invention asresearch relevant to its development was funded by NIH Grants AI26075,GM56008, HL48675, and AI25231.

BACKGROUND OF THE INVENTION

[0003] This present CEACAM1 is a member of the carcinoembryonic antigen(CEA) family. Isoforms of murine CEACAM1 serve as receptors for mousehepatitis virus (MHV), a murine coronavirus.

[0004] Carcinoembryonic antigen (CEA; CD66e) was initially discovered asa tumor antigen (Gold and Freedman, 1965). A large group of relatedglycoproteins is now called the CEA family within the Ig superfamily(IgSF). These anchored or secreted glycoproteins are expressed byepithelial cells, leukocytes, endothelial cells and placenta(Hammarstrom, 1999). In humans, the CEA family contains 29 genes orpseudogenes. The revised nomenclature of this family of glycoproteinswas recently summarized (Beauchemin et al., 1999). The CEA familyconsists of the CEACAM (CEA-related cell adhesion molecule) and PSG(pregnancy-specific glycoprotein) subfamilies whose proteins share manycommon structural features (Hammarstrom, 1999).

[0005] CEACAM1 (CD66a) is the most highly conserved member of the CEAfamily. Most species have only one CEACAM1 gene, but mice have twoclosely related genes called CEACAM1 and CEACAM2 (Beauchemin et al.,1999, Nedellec et al. 1994). CEACAM1 has many important biologicalfunctions. It is a potent vascular endothelial growth factor (Ergun etal., 2000) and a growth inhibitor in tumor cells (Izzi et al., 1999);plays a key role in differentiation of mammary glands (Huang et al.,1999); is an early marker of T cell activation; and modulates thefunctions of T lymphocytes (Morales et al., 1999; Nakajima et al.,2002). Human CEACAM 1 is one of several human CEACAM proteins that serveas receptors for virulent strains of Neisseria gonorrhoeae, Neisseriameningitidis, and Hemophilus influenzae (Bos et al., 1999; Virji et al.,2000; Virji et al., 1999).

[0006] In mice four isoforms of CEACAM1 generated by alternative mRNAsplicing have either 2 [D1,D4] or 4 [D1-D4] Ig-like domains on cellsurface, a transmembrane segment and either short or a long cytoplasmictail (Beauchemin et al., 1999). The long tail contains a modified ITIM(immunoreceptor tyrosine based inhibition motif)-like motif. Tyrosinephosphorylation of this motif is associated with signaling (Huber etal., 1999), but the natural ligands for the ecto-domain and themodulation of gene expression by CEACAM1 signaling are not wellunderstood.

[0007] All four isoforms of murine CEACAM1a as well as murine CEACAM2can serve as receptors for mouse hepatitis virus (MHV) strain A59(MHV-A59) when the recombinant murine proteins are expressed at highlevels in a hamster cell line (BHK) (Dveksler et al., 1993a; Dveksler etal., 1991; Nedellec et al., 1994). MHVs are large, enveloped,positive-stranded RNA viruses in the Coronaviridae family in the orderNidovirales. Various MHV strains cause diarrhea, hepatitis, respiratory,neurological and immunological disorders in mice. Infection is initiatedby binding of the 180 kDa spike glycoprotein (S) on the viral envelopeto a CEACAM glycoprotein on a murine cell membrane. Most inbred mousestrains are highly susceptible to MHV infection, but SJL/J mice arehighly resistant. Susceptible strains are homozygous for the CEACAM1aallele that encodes the principal MHV receptor, while SJL/J mice arehomozygous for the CEACAM1b allele. CEACAM1b proteins have weaker MHVbinding and receptor activities than CEACAM1a proteins (Ohtsuka et al.,1996; Rao et al., 1997; Wessner et al., 1998).

[0008] What is known about the family of CEACAM1a proteins is that MHVstrains utilize the murine CEACAM1a proteins as receptors (Compton, S.R. (1994); Dveksler (1991), Dveksler et al. (1993)). The spike (S)glycoprotein of MHV attaches to the N domain (D1) of CEACAM1a (Dveksler,et al., 1993, Williams, et al.,(1998). Mutational analysis showed thatthe virus MHV, binds to the C-C′ loop of domain 1 of the CEACAM1aprotein (Rao, et al. (1997), Wessner, et al. (1998)). However, extensiveN-linked glycosylation has precluded crystallization of any CEA proteinsfor structural analysis. A need continues to exist in the art definingthe basic structure of this important family of proteins, as to do sowould permit the development of a broad spectrum of therapeutic agentsfor viral, bacterial, immunological and carcinogenic pathologies.

SUMMARY OF THE INVENTION

[0009] The present invention, in a general and overall sense, relates tothe identification of a uniquely crystalline structure of a biologicallyimportant molecule that to this time had been precluded by the extensiveglycosylation inherent in the native CEA antigen. The structure of thebiologically active CC′ loop of the N-terminal domain (domain 1) couldnot have been predicted based on a comparison of its linear amino acidsequence with that of any other known structure of any other protein inthe database. The identification of this structure may be used in theselection and screening of agents for use in treatment of viral,bacterial, immunological diseases, malignancies and abnormal bloodvessel growth. The crystal structure of soluble murine sCEACAM1a[1,4],is composed of two Ig-like domains. This protein has virus neutralizingactivity. Its N-terminal domain has a uniquely folded CC′ loop thatencompasses key virus-binding residues, these are KGNTTAIDKE (SEQ ID NO:3). This is the first atomic structure of any member of the CEA family,and provides a prototypic architecture for functional identification ofall other CEA family members. The structural basis of virus receptoractivities of murine CEACAM1 proteins, binding of Neisseria to humanCEACAM1, and other homophilic and heterophilic interactions of CEAfamily members is disclosed in the present invention. This structuralinformation is also presented as embodiments of the invention thatprovides a method for screening molecules potentially useful astherapeutic agents in treating pathology where receptor interactions ofthis nature is important in the disease state.

[0010] In some embodiments, the invention provides a crystal structureof a soluble ecto-domain of an isoform of murine CEACAM1a that compressdomains 1 and 4, (designated msCEACAM1a[1,4] hereafter) and has MHVneutralizing activity. The relationship of the structure of themsCEACAM1a[1,4] glycoprotein to its MHV binding and neutralizingactivities is examined and described here. Based on the structure ofmsCEACAM1a[1,4], the invention in yet another aspect provides a model ofhuman CEA family members. The models of two N-terminal domains of humanCEACAM1, CEA and CEACAM6 provide particular embodiments of theinvention. Based on the models of CEA and CEACAM6, a strategy ofantibody development as well as other types of molecules capable ofbinding or inhibiting binding to the antigen is presented. Thebiological use of these structures in a pharmaceutical is disclosed.

[0011] The following terms, if appearing herein, shall have thedefinitions set out below.

[0012] The term “fragment”, as applied herein to a peptide, refers to atleast 7 contiguous amino acids, preferably about 14 to 16, 20, 25, 30 or36 contiguous amino acids, or up to more than 40 or 203 to 250 to 1500contiguous amino acids in length. Such peptides can be produced bywell-known methods to those skilled in the art, such as, for example, byproteolytic cleavage, genetic engineering or chemical synthesis.

[0013] The term “domain” refers to a compact, independently foldedtertiary structural unit, usually consisting of 50-200 amino acidresidues within a protein. A protein can have more than one domains toperform its function.

[0014] Unless defined otherwise, the scientific and technological termsand nomenclature used herein have the same meaning as commonlyunderstood by a person of ordinary skill to which the inventionpertains. Generally, the procedures for cell cultures, infection,molecular biology methods and the like are common methods used in theart. Such standard techniques can be found in reference manuals such asfor example J. Sambrook, D. W. Russell, Third Edition. (2001, MolecularCloning—A Laboratory Manual, Cold Spring Harbor Laboratories), andAusubel et al. (1994. Current protocols in Molecular Biology, Wiley, NewYork).

[0015] As used herein, “nucleic acid molecule”, refers to a polymer ofnucleotides. Non-limiting examples thereof include DNA (e.g. genomicDNA, cDNA), RNA molecules (e.g. mRNA) and chimeras thereof. The nucleicacid molecule can be obtained by cloning techniques or synthesized. DNAcan be double-stranded or single-stranded (coding strand or non-codingstrand [antisense]). RNA can be single-stranded or double-stranded, orpartially double stranded.

[0016] The term “DNA segment” is used herein to refer to a DNA moleculecomprising a linear stretch or sequence of nucleotides. This sequencewhen read in accordance with the genetic code, can encode a linearstretch or sequence of amino acids which can be referred to as apolypeptide, protein, protein fragment and the like.

[0017] As used herein, “oligonucleotides” or “oligos” define a moleculehaving two or more nucleotides (ribo or deoxyribonucleotides). The sizeof the oligo will be dictated by the particular situation and ultimatelyby the particular use thereof and adapted accordingly by the person ofordinary skill. An oligonucleotide can be synthetised chemically orderived by cloning according to well known methods.

[0018] The nucleic acid (e.g. DNA or RNA) for practicing the presentinventions may be obtained according to well known methods.

[0019] The term “DNA” molecule or sequence refers to a moleculegenerally comprised of the deoxyribonucleotides adenine (A), guanine(G), thymine (T), and/or cytosine (C), which in a double-stranded form,can comprise or include a “regulatory element”, as the term is definedherein. “DNA” can be found in linear DNA molecules or fragments,viruses, plasmids, vectors, chromosomes or synthetically derived DNA. Asused herein, particular double-stranded DNA sequences may be describedaccording to the normal convention of giving only the sequence in the 5′to 3′ direction. The same applies to single stranded DNA sequences. Aswell known in the art, DNA can also be found as circular molecules.

[0020] “Nucleic acid hybridization” refers generally to thehybridization of two single stranded nucleic acid molecules havingcomplementary base sequences, which under appropriate conditions willform a thermodynamically favored double-stranded structure. Examples ofhybridization conditions can be found in the two laboratory manualsreferred above (Sambrook and Russell, (2001), and Ausubel et al. (2001)and are well known in the art. In the case of a hybridization to anitrocellulose filter, as for example in the well known Southernblotting procedure, a nitrocellulose filter can be incubated overnightat 65° C. with a labelled probe in a solution containing 50% formamide,high salt (5×SSC or 5 x SSPE), 5× Denhardt's solution, 1% SDS, and 100μg/ml denatured carrrier DNA (e.g. salmon sperm DNA). Thenon-specifically binding probe can then be washed off the filter byseveral washes in 0.2×SSC/0.1% SDS at a temperature which is selected inview of the desired stringency: room temperature (low stringency), 42°C. (moderate stringency) or 65° C. (high stringency). The selectedtemperature is based on the melting temperature (Tm) of the DNA hybrid.Of course, RNA-DNA hybrids can also be formed and detected. In suchcases, the conditions of hybridization and washing can be adaptedaccording to well known methods by the person of ordinary skill.Stringent conditions will be preferably used (Sambrook and Russell,(2001)).

[0021] Probes of the invention can be utilized with naturally occurringsugar-phosphate backbones as well as modified backbones includingphosphorothioates, dithionates, alkyl phosphonates and nucleotides andthe like. Modified sugar-phosphate backbones are generally taught byMiller, (1998) and Moran (1997). Probes of the invention can beconstructed of either ribonucleic acid (RNA) or deoxyribonucleic acid(DNA).

[0022] The types of detection methods in which probes can be usedinclude Southern blots (DNA detection), dot or slot blots (DNA, RNA),and Northern blots (RNA detection). Although less preferred, labelledproteins could also be used to detect a particular nucleic acid sequenceto which it binds. Other detection methods include kits containingprobes on a dipstick setup and the like.

[0023] Probes can be labelled according to numerous well known methods(Sambrook and Russell (2001)). Non-limiting examples of labels include³H, ¹⁴C, ³²P, and ³⁵S. Non-limiting examples of detectable markersinclude ligands, fluorophores, chemiluminescent agents, enzymes, andantibodies. Other detectable markers for use with probes, which canenable an increase in sensitivity of the method of the invention,include biotin and radionucleotides. It will become evident to theperson of ordinary skill that the choice of a particular label dictatesthe manner in which it is bound to the probe.

[0024] As commonly known, radioactive nucleotides can be incorporatedinto probes of the invention by several methods. Non-limiting examplesthereof include kinasing the 5′ ends of the probes using gamma ³²P ATPand polynucleotide kinase, using the Klenow fragement of Pol 1 of E.coli in the presence of radioactive dNTP (e.g. uniformly labelled DNAprobe using random oligonucleotide primers in low-melt gels), using theSP6/T7 system to transcribe a DNA segment in the presence of one or moreradioactive NTP, and the like.

[0025] As used herein, a “primer” defines an oligonucleotide which iscapable of annealing to a target sequence, thereby creating a doublestranded region which can serve as an initiation point for DNA synthesisunder suitable conditions. In a particularly preferred embodiment, theprimer is a single stranded DNA molecule.

[0026] Amplification of a selected, or target, nucleic acid sequence maybe carried out by a number of suitable methods. Numerous amplificationtechniques have been described and can be readily adapted to suitparticular needs of a person of ordinary skill. Non-limiting examples ofamplification techniques include polymerase chain reaction (PCR), ligasechain reaction (LCR), strand displacement amplification (SDA),transcription-based amplification, the Qβ replicase system and NASBA(Sambrook and Russell, 2001, supra). Preferably, amplification will becarried out using PCR.

[0027] Polymerase chain reaction (PCR) is carried out in accordance withknown techniques. See, e.g., U.S. Pat. Nos. 4,683,195; 4,683,202;4,800,159; and 4,965,188 (the disclosures of all three U.S. Patents areincorporated herein by reference). In general, PCR involves, a treatmentof a nucleic acid sample (e.g., in the presence of a heat stable DNApolymerase) under hybridizing conditions, with one oligonucleotideprimer for each strand of the specific sequence to be detected. Anextension product of each primer which is synthesized is complementaryto each of the two nucleic acid strands, with the primers sufficientlycomplementary to each strand of the specific sequence to hybridizetherewith. The extension product synthesized from each primer can alsoserve as a template for further synthesis of extension products usingthe same primers. Following a sufficient number of rounds of synthesisof extension products, the sample is analysed to assess whether thesequence or sequences to be detected are present. Detection of theamplified sequence may be carried out by visualization following EtBrstaining of the DNA following gel electrophores, or using a detectablelabel in accordance with known techniques, and the like.

[0028] Ligase chain reaction (LCR) is carried out in accordance withknown techniques (Weiss, 1991, Science 254:1292). Adaptation of theprotocol to meet the desired needs can be carried out by a person ofordinary skill. Strand displacement amplification (SDA) is also carriedout in accordance with known techniques or adaptations thereof to meetthe particular needs.

[0029] As used herein, the term “gene” is well known in the art andrelates to a nucleic acid sequence defining a single protein orpolypeptide. A “structural gene” defines a DNA sequence which istranscribed into RNA and translated into a protein having a specificamino acid sequence thereby giving rise to a specific polypeptide orprotein. It will be readily recognized by the person of ordinary skill,that the nucleic acid sequence of the present invention can beincorporated into any one of numerous established kit formats which arewell known in the art.

[0030] A “heterologous” (e.g. a heterologous gene) region of a DNAmolecule is a subsegment of DNA within a larger segment that is notfound in association therewith in nature. The term “heterologous” can besimilarly used to define two polypeptide segments not joined together innature. Non-limiting examples of heterologous genes include reportergenes such as luciferase, chloramphenicol acetyl transferase,beta-galactosidase, and the like which can be juxtaposed or joined toheterologous control regions or to heterologous polypeptides.

[0031] The term “vector” is commonly known in the art and defines aplasmid DNA, phage DNA, viral DNA and the like, which can serve as a DNAvehicle into which DNA of the present invention can be cloned. Numeroustypes of vectors exist and are well known in the art.

[0032] The term “expression” defines the process by which a gene istranscribed into one or more mRNAs (transcription), the mRNA is thenbeing translated (translation) into one polypeptide (or protein) ormore.

[0033] The terminology “expression vector” defines a vector or vehicleas described above but designed to enable the expression of an insertedsequence following transformation into a host. The cloned gene (insertedsequence) is usually placed under the control of control elementsequences such as promoter sequences. The placing of a cloned gene undersuch control sequences is often referred to as being operably linked tocontrol elements or sequences.

[0034] Operably linked sequences may also include two segments that aretranscribed onto the same RNA transcript. Thus, two sequences, such as apromoter and a “reporter sequence” are operably linked if transcriptioncommencing in the promoter will produce an RNA transcript of thereporter sequence. In order to be “operably linked” it is not necessarythat two sequences be immediately adjacent to one another.

[0035] Expression control sequences will vary depending on whether thevector is designed to express the operably linked gene in a prokaryoticor eukaryotic host or both (shuttle vectors) and can additionallycontain transcriptional elements such as enhancer elements, terminationsequences, tissue-specificity elements, and/or translational initiationand termination sites.

[0036] Prokaryotic expression systems are useful for the preparation oflarge quantities of the protein encoded by the DNA sequence of interest.This protein can be purified according to standard protocols that takeadvantage of the intrinsic properties thereof, such as size and charge(e.g. SDS gel electrophoresis, gel filtration, centrifugation, ionexchange chromatography, reverse phase chromatography, etc.). Inaddition, the protein of interest can be purified via affinitychromatography, for example, using polyclonal or monoclonal antibodiesor nickel affinity chromatography.

[0037] The DNA construct can be a vector comprising a promoter that isoperably linked to an oligonucleotide sequence, which is in turn,operably linked to a heterologous gene, such as the gene for theluciferase reporter molecule. “Promoter” refers to a DNA regulatoryregion capable of binding directly or indirectly to RNA polymerase in acell and and initiating transcription of a downstream (3′ direction)coding sequence. For purposes of the present invention, the promoter isbound at its 3′ terminus by the transcription initiation site andextends upstream (5′ direction) to include the minimum number of basesor elements necessary to initiate transcription at levels detectableabove background. Within the promoter will be found a transcriptioninitiation site (conveniently defined by mapping with S1 nuclease), aswell as protein binding domains (cosensus sequences) responsible for thebinding of RNA polymerase. Eukaryotic promoters will often, but notalways, contain “TATA” boxes and “CCAT” boxes. Prokaryotic promoterscontain −10 and −35 consensus sequences, which serve to initiatetranscription and the transcript products contain Shine-Dalgarnosequences, which serve as ribosome binding references during translationinitiation.

[0038] As used herein, the designation “functional derivative”, thecontext of a functional derivative denotes, in the context of afunctional derivative of a sequence whether a nucleic acid or amino acidsequence, a molecule that retains a biological activity (either functionor structural) that is substantially similar to that of the originalsequence (e.g. acting as receptor for viral infection). This functionalderivative or equivalent may be a natural derivative or may be preparedsynthetically. Such derivatives include amino acid sequences havingsubstitutions, deletions, or additions of one or more amino acids,provided that the biological activity of the protein is conserved. Thesame applies to derivatives of nucleic acid sequences which can havesubstitutions, deletions, or additions of one or more nucleotides,provided that the biological activity of the sequence is generallymaintained. When relating to a protein sequence, the substituting aminoacid has chemico-physical properties which are similar to those of thesubstituted amino acid. The similar chemico-physical properties includesimilarities in charge, bulkiness, hydrophobicity, hydrophilicity andthe like. The term “functional derivatives” is intended to include“fragments”, “segments”, “variants”, “analogs”, or “chemicalderivatives” of the subject matter of the present invention.

[0039] As well-known in the art, a conservative mutation or substitutionof an amino acid refers to mutation or substitution which maintains: 1)the structure of the backbone of the polypeptide (e.g. a beta sheet oralpha-helical structure); 2) the charge or hydrophobicity of the aminoacid; or 3) the bulkiness of the side chain. More specifically, thewell-known terminologies “hydrophilic residues” relate to serine,threonine, glutamine or asparagine. “Hydrophobic residues” refer toleucine, isoleucine, alanine, methionine, valine or proline. “Positivecharged residues” refer to lysine, arginine or histidine. “Negativelycharged residues” refer to aspartic acid or glutamic acid. Residueshaving “bulky side chains” refer to phenylalanine, tryptophan ortyrosine.

[0040] The term “variant” refers herein to a protein or nucleic acidmolecule which is substantially similar in structure and biologicalactivity to the protein, peptide, or nucleic acid described in thepresent invention.

[0041] The term “allele” defines an alternative form of a gene thatoccupies a given locus on a chromosome. Non-limiting examples thereofare exemplified with murine CEACAM1^(a) and CEACAM1^(b).

[0042] As commonly known, a “mutation” is a detectable change in thegenetic material which can be transmitted to a daughter cell. A mutationcan be, for example, a detectable change in one or moredeoxyribonucleotide or amino acid. For example, nucleotides or aminoacids can be added, deleted, substituted for, inverted, or transposed toa new position. Spontaneous mutations and experimentally inducedmutations exist. The result of a mutations of nucleic acid or amino acidmolecule is a mutant molecule. A mutant polypeptide can be encoded fromthis mutant nucleic acid molecule.

[0043] It shall be understood that an in vitro assay may be used todemonstrate the utility of the particular molecule being examined as auseful therapeutic in vivo. For example, cellular extracts from ananimal or purified animal testing extract of cells such as T-cells canbe prepared and used as representative vitro to demonstrate thefunctionality and utility of the molecule as immunomolulatory molecule.An in vitro assay could be used to compare the infectious potential ofinfectious agents on extracts prepared from animal tissue in this samemanner.

[0044] As used herein in the recitation “indicator cells” refers tocells that express, in one particular embodiment, the CEACAM1glycoprotein or domains thereof which interact with a viral protein orother cellular protein which is directly or indirectly involved ininfection by the virus or other molecular interactions of CEACAM 1, andwherein an interaction between these proteins or interacting domainsthereof is coupled to an identifiable or selectable phenotype orcharacteristic such that it provides an assessment of the interactionbetween same. Such indicator cells can be used in the screening assaysof the present invention. In certain embodiments, the indicator cellshave been engineered so as to express a chosen derivative, fragmnent,homologue, or mutant of these interacting domains. The cells can beyeast cells or preferably higher eukaryotic cells such as mammaliancells (WO 96/41169).

[0045] A host cell or indicator cell has been “transfected” by exogenousor heterologous DNA (e.g. a DNA construct) when such DNA has beenintroduced inside the cell. The transfecting DNA may or may not beintegrated (covalently linked) into chromosomal DNA making up the genomeof the cell. In prokaryotes, yeast, and mammalian cells for example, thetransfecting DNA may be maintained on an episomal cell element, such asa plasmid. With respect to eukaryotic cells, a stably transfected cellis one in which the transfecting DNA has become integrated into achromosome so that it is inherited by daughter cells through chromosomereplication. This stability is demonstrated by the ability of theeukaryotic cell to establish cell lines or clones comprised of apopulation of daughter cells containing the transfecting DNA.Transfection methods are well known in the art (Sambrook and Russell(2001), Ausubel et al., (1994)). C C′ loop, human CEACAM1 (10 a a) D1K-G-E-R-V-D-G-N-R-Q SEQ ID NO: 1 1                10

[0046] D1 loop, human CEACAM1 (1-107 aa) 1Q-L-T-T-E-S-M-P-F-N-V-A-E-G-K-E-V-L-L-L-V-H-N-L-P 25 SEQ ID NO: 2 26Q-Q-L-F-G-Y-S-W-V-K-G-E-R-V-D-G-N-R-Q-I-V-G-Y-A-I 50 51G-T-Q-Q-A-T-P-G-P-A-N-S-G-R-E-T-I-Y-P-N-A-S-L-L-I 75 76Q-N-V-T-Q-N-D-T-G-F-Y-T-L-Q-V-I-K-S-D-L-V-N-E-E-A 100 101 T-G-Q-F-H-V-Y107

BRIEF DESCRIPTION OF THE FIGURES

[0047]FIG. 1. Stereo view of the ribbon drawing of msCEACAM1a [1,4]which contains two Ig-like domains. The CC′-loop in the N-terminaldomain (D1) which is involved in binding of MHV and other ligands ismarked by an arrow. The predicted key virus-binding residue Ile41 on theCC′ loop is shown in ball-and-stick style. The FG loop of D1, anotherbiologically important element is also shown. The carbohydrate moietiesare drawn in ball-and-stick style. The glycan at Asn70 that is conservedin the whole CEA family is labeled. The figure was prepared usingMOLSCRIPT ®(Krulis, 1991).

[0048]FIG. 2(A)-2(C). Superposition of D1 of msCEACAM1a[1,4], CD2, CD4and Bence-Jones protein REI. Each molecule is shown in Cat trace, withmsCEACAM1a in a thick solid line (SEQ ID NO: 4), CD2 in a thin dashedline (SEQ ID NO: 5), CD4 in a solid line (SEQ ID NO: 6) and REI in athick dashed line (SEQ ID NO: 7), respectively. The uniquely convolutedconformation of the CC′ loop in msCEACAM1a[1,4] is striking. Thesequence alignment of the CC′ loop regions of these four molecules arealso shown using the same code (SEQ ID NOS 4-7, respectively in theorder of appearance). (2B) Stereo view of the exposed residues on theCFG face of D1 of msCEACAM1a[1,4]. The CaLtrace of the CC′ loop ishighlighted. Displayed sidechains and carbohydrates are drawn inball-and-stick style. (2C) Electrostatic potential surfacerepresentation of the same view as (B). FIGS. 2A and B were preparedwith MOLSCRIPT ® (Krulis, 1991), and 2C, with GRASP®) (Nicholls et al.,1991).

[0049]FIG. 3. A comparative view of structures of several virusreceptors, including msCEACAM1a, receptor for murine coronavirus MHV;ICAM1, receptor for the major group of rhinoviruses; CD4, primaryreceptor for HIV; and CD46, receptor for measles virus. Shown here areonly their N-terminal domains. Their key virus-binding motifs withuniquely topological features are also highlighted.

[0050]FIG. 4. Sequence alignment of D1 and D4 of murine CEACAM1 withcorresponding domains of human CEA family members. Residues invariantthroughout all sequences shown are in bold italics, courier (serif),whereas physico-chemically conserved residues (with no more than twoexceptions) are bold monospace (sans serif). The β-strands are shownunderlined. (4A) D1 of murine CEACAM1a (SEQ ID NO: 8) is aligned with D1of murine CEACAM1b (SEQ ID NO: 2) (upper panel), as well as the humanCEA members found in the SWISSPROT database (lower panel) (SEQ ID NOS10-24, respectively in the order of appearance). (4B) D4 of murineCEACAM1a (SEQ ID NO: 26) is aligned with D2 of the same molecule (upperpanel) (SEQ ID NO: 25). This marks potential N-glycosylation sites.These sequences are compared with the A1 (SEQ ID NO: 27), A2 (SEQ ID NO:28), A3 (SEQ ID NO: 29) and B1 (SEQ ID NO: 30), B2 (SEQ ID NO: 31), B3(SEQ ID NO: 32) domains of human CEA, the gene product of CEACAM5 (lowerpanel).

[0051]FIG. 5. Topology diagram for D1 of msCEACAM1a with β-strands shownas arrows. The diagram is coded according to the degree of variabilityin sequence of N-terminal domain for all available mammalian CEAmolecules. The variability was measured using Shannon's entropy value(H) (Stewart et al., 1997). The least variable, or most conserved,residues (H<1) are shown as a dotted region, whereas the most variableones (H>2) are depicted as an angled hatched region. Those residues inbetween (1<H<2) are depicted in a squared region. The difference in thedegree of sequence conservation between the ABED and CFG faces isevident. On the ABED face, the glycan at Asn 70 and the shieldedhydrophobic residues are marked.

[0052]FIGS. 6A and B. Backbone worm representation of the “parallel”interaction between the dyad-related msCEACAM1a[1,4] molecules seen inthe crystal structure, prepared with GRASP® (Nicholls et al., 1991).(6A) Two monomers are related by a crystallographic 2-fold axis, and areshown in a bold hatched line and a open hatched line, respectively.Carboydrates are drawn in ball-and-stick style. (6B) Stereo picture ofthe close-up view across the dimer interface. Those sidechain involvedin interactions are shown in ball-and -stick style.

[0053]FIG. 7 is the surface representation of the model, in which theglycan-protected areas for CEA is a cross-hatched area, labeled (I). Thearea shielded by glycans on CEACAM6 but not on CEA is labeled (II). Thewhite areas are exposed and they contain the potential Mabs epitopesthat recognize both CEA and CEACAM 6.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0054] The present invention is illustrated in further detail by thefollowing non-limiting examples. Although the following descriptions aredirected to preferred embodiments, namely a molecular model useful fordesigning compounds that modulate the interaction between the novelstructure of the CC′ loop of the carcinoembryonic antigen cell adhesionmolecule and other molecules (e.g. antibodies, proteins, peptides orother small molecules), as well as the various compounds that willsatisfy this criteria, it should be understood that this description isillustrated only and is not intended to limit the scope of theinvention.

[0055] The amino acid residues described herein are preferred to be inthe “L” isomeric form. However, residues in the “D” isomeric form can besubstituted for any L-amino acid residue, as long as the desiredfractional property of immunoglobulin-binding is retained by thepolypeptide. NH₂ refers to the free amino group present at the aminoterminus of a polypeptide. COOH refers to the free carboxy group presentat the carboxy terminus of a polypeptide. In keeping with standardpolypeptide nomenclature, J. Biol. Chem., 243:3552-59 (1969),abbreviations for amino acid residues are shown in the following Tableof Correspondence: TABLE OF CORRESPONDENCE SYMBOL 1-Letter 3-LetterAMINO ACID Y Tyr tyrosine G Gly glycine F Phe phenylalanine M Metmethionine A Ala alanine S Ser serine I Ile isoleucine L Leu leucine TThr threonine V Val valine P Pro proline K Lys lysine H His histidine QGln glutamine E Glu glutamic acid W Trp tryptophan R Arg arginine D Aspaspartic acid N Asn asparagine C Cys cysteine

[0056] It should be noted that all amino-acid residue sequences arerepresented herein by formulae whose left and right orientation is inthe conventional direction of amino-terminus to carboxy-terminus.Furthermore, it should be noted that a dash at the beginning or end ofan amino acid residue sequence indicates a peptide bond to a furthersequence of one or more amino-acid residues. The above Table ispresented to correlate the three-letter and one-letter notations whichmay appear alternately herein.

[0057] A number of articles review computer modeling of drugsinteractive with specific proteins, such as Rotivinen (1988); Ripka(1988); McKinaly and Rossmann (1989); Perry and Davies (1989); Lewis andDean (1989); and with respect to a model receptor for nucleic acidcomponents, Askew, et al. (1989). Other computer programs that screenand graphically depict chemicals are available from companies such asBioDesign, Inc. (Pasadena, Calif.), Allelix, Inc. (Mississauga, Ontario,Canada), and Hypercube, Inc. (Cambridge, Ontario).

[0058] Although described above with reference to design and generationof compounds which could alter binding, one could also screen librariesof known compounds, including natural products or synthetic chemicals,and biologically active materials, including proteins, for compoundswhich are inhibitors or activators.

[0059] Compounds identified via assays such as those described hereinmay be useful, for example, for treating any of the conditions disclosedherein that depend upon biological interactions of CEACAM1 orstructurally related proteins. Assays for testing the efficacy ofcompounds identified in the cellular screen can be tested in animalmodel systems for such conditions. Such animal models may be used astest substrates for the identification of drugs, pharmaceuticals,therapies and interventions which may be effective in treating suchconditions. For example, animal models may be exposed to a compoundsuspected of exhibiting an ability to ameliorate a condition mediated byCEACAM1 or related proteins at a sufficient concentration and for a timesufficient to elicit such an amelioration of condition-associatedsymptoms in the exposed animals. The response of the animals to theexposure may be monitored by assessing the reversal of symptomsassociated with the condition, such as an autoimmune condition or adelayed hypersensitivity response to an antigen, or by assessingprevention of infection with a virus or bacterium that depends uponbinding to CEACAM1 or structurally related proteins on host cellmembranes. With regard to intervention, any treatments that are based onthe homologous human sequence and structure which reverse any aspect ofsuch symptoms in an animal model system should be considered ascandidates for human therapeutic intervention, in this manner,homologous drugs to examine in humans would be prepared. Dosages of testagents may be determined by deriving dose-response curves, in accordancewith standard practice.

[0060] According to still another aspect of the invention, low molecularweight compounds that inhibit the interaction between CEACAM1 orstructurally related proteins, peptides or other biologically importantmolecules, to and their natural ligands in the body, or to proteins ofbacteria or viruses that use these molecules as receptors are provided.These compounds can be used to modulate the interaction, or can be usedas lead compounds for the design of better compounds using theabove-described computer-based rational drug design methods.

[0061] As also described in U.S. Pat. No. 5,908,609, exemplary librarycompounds include, but are not limited to, peptides such as, forexample, soluble peptides, including but not limited to members ofrandom peptide libraries; (see, e.g., Lam, K. S. et al., (1991);Houghten, R. et al., (1991)), and combinatorial chemistry-derivedmolecular libraries made of D-and/or L-configuration amino acids,phosphopeptides (including but not limited to, members of random orpartially degenerate, directed phosphopeptide libraries; (see, e.g.,Songyang, Z. et al., (1993)); antibodies (including, but not limited to,polyclonal, monoclonal, humanized, anti-idiotypic, chimeric or singlechain antibodies, and Fab, F(ab), sub. 2 and Fab expression libraryfragments, and epitope-binding fragments thereof), and small organic orinorganic molecules. Other compounds which can be screened in accordancewith the invention include but are not limited to small organicmolecules that are able to gain entry into an appropriate cell andaffect the interaction of CEACAM1 (or structurally related proteins inthe CEA family) with its natural ligands in vivo or with bacteria orviruses. For example, the compounds of the invention that can bedesigned to satisfy the foregoing criteria include polypeptides andpeptide mimetics. The peptide mimetic can be a hybrid molecule whichincludes both amino acid and non-amino acid components, e.g., the mimiccan include amino acid components for the positively charged andnegatively charged regions and non-amino acid (e.g., piperidine) havingthe same approximate size and dimension of a hydrophobic amino acid(e.g., phenylalanine) as the hydrophobic component.

[0062] In certain embodiments, the screening assay is designed toidentify agents which modulate the interaction of the CEACAM1 orstructurally related protein with the viral spike glycoprotein or abacterial adhesion molecule or outer membrane protein (referred to inthe art as a heterophilic interaction) and not interfere with homophilicinteractions (e.g., CEACAM1 binding to another CEACAM1 or structurallyrelated molecule). In this manner, agents can be selected whichadvantageously affect only the interaction of CEACAM1 or structurallyrelated proteins with bacteria or viruses, without adversely affectingother natural cellular functions of these polypeptides. In these andother embodiments, the assays optionally involve the step of introducingthe compound into an animal model of a condition mediated by theinteraction of CEACAM1 or structurally related proteins and pathogenicbacteria or viruses and determining whether the compound preventsinfection or alleviates the symptoms of the condition. At the same time,the natural cellular functions of CEACAM1 in cell adhesion, immuneinteractions, angiogenesis, etc. would be assayed to assure that thesewere normal, i.e., within pharmacological acceptable levels.

[0063] In general, the assay can be of any type, provided that the assayis capable of detecting the interaction of a CEACAM1 or structurallyrelated protein and a natural ligand. Preferably, the assay is a bindingassay (e.g., an adhesion assay)which detects adhesion between theCEACAM1 or structurally related protein and the domain or polypeptide ofthe natural ligand that binds to CEACAM1 or related protein. Exemplaryadhesion assays are described in the Examples. In general, such assayscan be performed using cell-free or cell-based systems, e.g., thepolypeptide components can be isolated or can be expressed on thesurface of a cell. Additionally, or alternatively, the assay can be asignaling assay which detects signaling events following interaction ofthe ligand or domain of the ligand and the CEACAM1 (or related ) proteinor the ligand-binding domain of CEACAM1. In such instances, thesignaling assay typically is a cell-based assay in which the CEACAM1protein is expressed on a cell. In a cell signaling assay, a down-streameffect (e.g., a change in cytokine expression, enhanced expression ofanother gene) or altered expression of a receptor due to CEACAM1 bindingto the ligand or the CEACAM1-binding domain of the ligand is detected,rather than detecting only the adhesion of these molecules to oneanother.

[0064] Regardless of the particular type of assay, in some embodiments,the assays of the invention may utilize an isolated ligand for CEACAM1,unless the assay further involves the selection of a molecular library,which takes into account the information presented herein with respectto the approximate size and charge characteristics of prospectivemodulators of the interaction. In the latter instances, the CC′ loop ofCEACAM1 or a domain of its natural ligand that binds to the CC′ loop ofCEACAM1 may form part of a synthesized or recombinant polypeptide thatmay or may not be complexed to a marker polypeptide or molecule. Theassays of the invention may utilize CEACAM1 protein which is completeor, alternatively, which contains a CEACAM1 N-terminal domain (e.g., atleast an isolated domain but not the entire 4 domain anchored CEACAM1polypeptide sequence). The protein or peptide may be used in isolatedform (e.g., immobilized to a solid support or as a soluble fusionprotein as described in the examples) or expressed on the surface of acell (e.g., an epithelial cell, an endothelial cell, or other cellgenetically engineered to express the CEACAM1). The ligand polypeptidethat binds to the CC′ loop of CEACAM1 (such as a viral spikeglycoprotein, or bacterial outer membrane protein, or homophilic bindingdomain of CEACAM1, or a monoclonal antibody) likewise may be used inisolated form or expressed on the surface of a cell.

[0065] As used herein in reference to a peptide, the term “isolated”refers to a cloned expression product of an oligonucleotide; a peptidewhich is isolated following cleavage from a larger polypeptide; or apeptide that is synthesized, e.g., using solution and/or solid phasepeptide synthesis methods as disclosed in, for example, U.S. Pat. No.5,120,830, the entire contents of which are incorporated herein byreference. Accordingly, the phrase “isolated peptides” embraces peptidefragments of CEACAM1 or its ligands as well as functionally equivalentpeptide analogs of the foregoing peptide fragments. As used herein, theterm “peptide analog” refers to a peptide which shares a commonstructural feature with the molecule to which it is deemed to be ananalog. A “functionally equivalent” peptide analog is a peptide analogwhich further shares a common functional activity with the molecule towhich it is deemed an analog. Alternatively, the binding partners in theadhesion assays can be the particular ligands and receptors whichmediate intercellular adhesion. For example, the binding of alymphocyte, macrophage, polymorphonuclear cell or dendritic cell to anepithelial or endothelial cell may be mediated via the specificinteraction of CEACAM1 and CEACAM1(on the epithelial cell). Accordingly,adhesion assays can be performed in which the binding partners are: (1)interacting cells (e.g. a lymphocyte and an epithelial cell, or alymphocyte and a dendritic cell); (2) a cell expressing a ligand (e.g.an lymphocyte expressing CEACAM1 or a structurally related protein) andan isolated receptor (e.g. soluble recombinant CEACAM1) for the ligand;(3) an isolated ligand and a cell expressing the receptor for theligand; and (4) an isolated ligand and its isolated receptor (e.g.soluble CEACAM1a[1,4] and MHV viral spike protein).

[0066] Thus, a high throughput screening assay for selectingpharmaceutical lead compounds can be performed. In one embodiment, thescreening assay as a method of selecting pharmaceutical lead compoundswill comprise the following steps: (1) immobilizing CEACAM1 onto asurface of a microtiter well having a plurality of wells, (2) adding analiquot of a molecular library containing library members selected inaccordance with methods of the invention 3) adding cells expressing aligand for CEACAM1 (e.g. lymphocytes) to the wells and (4) incubatingthe well components are allowed to incubate for a period of time that issufficient for the cells to bind to immobilized CEACAM1. Preferably, thecells (or soluble CEACAM1-binding protein or peptide) are labeled (e.g.,preincubated with Cr 51 or a fluorescent dye) prior to their addition tothe microtiter well. Following the incubation period, washing the wellsto remove non-adherent cells and the signal attributable to the label onthe remaining attached lymphocytes is determined. A positive control(e.g., a cell type that is known to bind to CEACAM1) on the samemicrotiter plate is used to establish maximal adhesion value. A negativecontrol (e.g., soluble CEACAM1 added to the microtiter well) on the samemicrotiter plate is used to establish maximal levels of inhibition ofadhesion.

[0067] The screening methods of the invention provide useful informationfor the rational drug design of novel agents which are, for example,capable of modulating an immune system response, or blocking viral orbacterial infection. In addition to the above-noted computer modelprograms, exemplary procedures for rational drug design are provided inSaragovi, H. er al., (1992); Haber E. (1983)(:1967); and Connolly Y.,(1991) (“Computer-Assisted Rational Drug Design”: pp 587-616), thecontents of which are incorporated herein by reference.

[0068] Thus, knowledge of the structure (primary, secondary or tertiary)of naturally occurring ligands and receptors can be used to rationallychoose or design molecules which will bind with either the ligand orreceptor. In particular, knowledge of the binding regions of ligands andreceptors can be used to rationally choose or design compounds which aremore potent than the naturally occurring ligands in eliciting theirnormal response or which are competitive inhibitors of theligand-receptor interaction.

[0069] Once rationally chosen or designed and selected, the librarymembers may be altered, e.g., in primary sequence, to produce new anddifferent peptides. These fragments may be produced by site-directedmutagenesis or may be synthesized in vitro. These new fragments may thenbe tested for their ability to bind to the receptor or ligand and, byvarying their primary sequences and observing the effects, peptides withincreased binding or inhibitory ability can be produced. For example,improved compounds which modulate the interaction of a cell adhesionassay can be made by making conservative amino acid substitutes inpeptides (e.g., Formula I) that are designed to fit in the active sitedefined by the docking model disclosed herein. As used herein,“conservative amino acid substitution” refers to an amino acidsubstitution which does not substantially alter the relativephysico-chemical characteristics of the peptide in which the amino acidsubstitution is made.

[0070] It will be appreciated by those skilled in the art that variousmodifications of the foregoing peptide analogs can be made withoutdeparting from the essential nature of the invention. Accordingly, it isintended that peptides which include conservative substitutions andcouples proteins in which a peptide of the invention is coupled to asolid support (such as a polymeric bead), a carrier molecule (such askeyhole limpet hemocyanin), a toxin (such as ricin) or a reporter group(such as radiolabel or other tag), also are embraced within theteachings of the invention.

[0071] The screening assays of the invention are useful for identifyingpharmaceutical lead compounds in molecular libraries. A “molecularlibrary” refers to a collection of structurally-diverse molecules.Molecular libraries can be chemically-synthesized or recombinantlyproduced. As used herein, a “molecular library member” refers to amolecule that is contained within the molecular library. Accordingly,“screening” refers to the process by which library molecules are testedfor the ability to modulate (i.e., inhibit or enhance) interactionbetween a CEACAM1 or structurally related protein and a naturallyoccurring ligand, or a viral protein or bacterial protein or an antibodyspecific for CEACAM1, particularly the biologically active CC′ loopwhich has the unique structure described herein. As used herein, a“pharmaceutical lead compound” refers to a molecule example. Screeningassays are useful for assessing the ability of a library molecule toinhibit the binding of a CEACAM1 ligand (or an polypeptide derived fromCEACAM1 or structurally related protein) to a natural ligand.

[0072] Libraries of structurally diverse molecules can be prepared usingchemical and/or recombinant technology. Such libraries for screeninginclude recombinantly produced libraries of fusion proteins. Anexemplary recombinantly produced library is prepared by ligatingfragments of CEACAM1 or related protein into, for example, the pGEX2Tvector (Pharmacia, Piscataway, N.H.). This vector contains the carboxyterminus of glutathion S-transfersse (GST) from Schistosoma japonicum.Use of the GST-containing vector facilitates purification ofGST-polypeptide fusion proteins from bacterial lysates by affinitychromatography on glutathione sepherose. After elution from the affinitycolumn, the fusion proteins are tested for activity by, for example,subjecting the fusion protein to the screening assays disclosed herein.Fusion proteins which inhibit binding between CEACAM1 expressing cellsare selected as pharmaceutical lead compounds and/or to facilitatefurther characterization of the portion of the lead compound whichblocks homophilic binding.

[0073] The methods of the invention are useful for identifying novelcompounds that are capable of modulating a mucosal immune response invivo. Accordingly, the invention further provides a pharmaceuticalpreparation for modulating a mucosal immune response in a subject isprovided. The composition includes a pharmaceutically acceptable carrierand an agent that inhibits interaction (e.g., adhesion) between CC′loops of CEACAM1 molecules. In particularly preferred embodiments, theagent inhibits homophlic adhesion between CEACAM1-expressing cells. Theagent (e.g., the above-described peptide) is present in atherapeutically effective amount for treating the immune response ortreating or preventing viral or bacterial infection. Thus, in a relatedaspect, the invention also provides a method for modulating the mucosalimmune response of a subject. The method involves administering to thesubject a pharmaceutical composition comprising the above-describedagents for inhibiting adhesion between CEACAM1-expressing cells. Inaddition, the same compounds can be tested for the ability to inhibit ortreat bacterial or viral infections of microbes that use CEACAM1 asreceptors.

[0074] In general, the therapeutically effective amount is between about1 mg and about 100 mg/kg. The preferred amount can be determined by oneof ordinary skill in the art in accordance with standard practice fordetermining optimum dosage levels of the agent. The compounds areformulated into a pharmaceutical composition by combination with anappropriate pharmaceutically acceptable carrier. For example, thecompounds may be used in the form of their pharmaceutically acceptablesalts, or may be used alone or in appropriate association, as well as incombination with other pharmaceutically active compounds. The compoundsmay be formulated into preparations in solid, semisolid liquid, orgaseous form such as tablets, capsules, powders, granules, ointments,solutions, suppositories, inhalants and injections, in usual ways fororal, parenteral, or surgical administration. Exemplary pharmaceuticallyacceptable carriers are described in U.S. 5,211,657, the entire contentsof which patent are incorporated herein by reference. The invention alsoincludes locally administering the composition as an implant.

[0075] In order for this invention to be fully understood, the followingexamples are set forth. These examples are for the illustrative purposeonly and not to be seen as limiting the scope of this invention.

EXAMPLE 1 Protein Expression and Purification

[0076] Nucleotide sequences encoding the first 236 amino acids of murineCEACAM1a[1,4] including the natural 34 aa long signal sequence wereamplified by PCR using an oligonucleotide that added an XbaI site inframe at the 3′ end. This DNA was ligated in frame into a previouslydescribed construct encoding a thrombin cleavage peptide followed by sixhistidine residues and a stop codon (Zelus et al., 1998), and insertedinto the pShuttle CMV vector (He et al., 1998). This construct wasinserted into the pAd-Easy adenovirus vector, and adenoviruses thatcontained the cDNA were plaque purified and amplified in 293 cells aspreviously described (He et al., 1998). Lec-CHO cells stably transfectedwith CAR, the Coxsackie/adenovirus receptor were transduced with theCEACAM1a[1,4]-containing adenovirus. The soluble, his-tagged murineCEACAM1a[ 1,4] protein from the supernatant medium was purified bynickel affinity chromatography on a Pharmacia HiTrap chelating column,and eluted with imidazole. Fractions containing the protein wereidentified by immunoblotting with polyclonal rabbit antibody directedagainst murine CEACAM1a, and the pooled fractions were dialyzed against25 mM Tris buffer, pH 9.0, with 5% glycerol. The protein was furtherpurified by ion exchange chromatography on a HQ20 (Poros) column andeluted in a sodium chloride gradient. Fractions containing the proteinwere pooled, dialyzed against 25 mM TRIS pH (7.6), 150 MM NaCl, 5%glycerol, and stored at −80° C. The purity of the proteins wasdetermined by silver staining of SDS-PAGE gels and by Western blottingwith anti-CEACAM1a antibody. The medium of 40 T150 flasks of adenovirustransduced lec-, CAR+CHO cells yielded approximately 0.5 to 1 mg ofpurified msCEACAM1a[1,4] protein.

EXAMPLE 2 Crystallization and X-ray Data Collection

[0077] Single crystals of msCEACAM1a[1,4] were grown from acrystallization buffer containing 10% PEG 8000, 0.2 M magnesium acetateand 0.1 M cacodylate at pH 6.4 using the vapor-diffusion hanging dropmethod. For data collection at cryogenic temperature, the crystals weretreated with a cryoprotectant solution (25% glycerol, 10% PEG 8000 and0.1 M cacodylate), then frozen and stored in liquid nitrogen. Platinumderivatives were prepared by soaking the crystals overnight in the samecryo-protectant solution containing 0.5 mM K₂PtBr₄.

[0078] X-ray diffraction data were collected from pre-frozen crystals atAPS SBC 19ID in Argonne National Laboratories at a temperature of 100°K. A native crystal diffracted to a resolution of 3.32 Å, with onemolecule in one asymmetric unit. A multi-wavelength anomalousdiffraction (MAD) data set of the platinum derivative was obtained to aresolution of 3.85 Å. All the raw data were indexed and reduced withHKL2000 (Otwinowski and Minor, 1997)(Table I).

EXAMPLE 3

[0079] Structure Determination and Refinement

[0080] The msCEACAM1a[1,4] structure was solved using the MAD phases incombination with molecular replacement (MR). Using programs in the CCP4suite (CCP4, 1994), one Pt binding site was identified in one asymmetricunit in both difference and anomalous difference Patterson maps. Heavyatom parameters were refined at 4 Å resolution with the program MLPHAREin CCP4 suite, and an additional platinum site was identified. Phaseextension was performed using the native data set to 3.32 Å by solventflattening and histogram matching with DM. The resulting phases wereused to carry out a phased molecular replacement with ROTPTF on theBronx X-ray server for the two separate domains. The N-terminal domainsof CD2 (PDB code 1HNF) and human Fc-γ receptor III (PDB code 1E4J) wereused as search models for the D1 and D4 domains of msCEACAM1a[1,4],respectively. The model was traced with XtalView(http://www.scripts.edu/pub/dem-web) on the basis of the MAD phases,using the MR solutions as a guideline.

[0081] After cycles of model building using program 0 (Jones et al.,1991) and refinement, the final model was refined at 3.32 Å resolutionto an R_(free) factor of 32.9% and R_(work) of 29.5% (Table I) using theXplor (Brunger, 1992). At 1.5σ contour level (σ=0.125 e/Å³) in 2Fo-Fcmap, there was continuous density for the main chain backbone. The finalmodel contains 203 residues (from Glu1 to Thr203) and a total of 6 sugarresidues associated with four of the five potential glycosylation sites.There was no visible electron density beyond residue Thr203 where morethan a dozen residues including a his-tag are present in the expressionconstruct. These C-terminal residues are apparently disordered. Thecurrent model also includes a total of 26 water molecules. Some of thedensities assigned to solvent molecules around the end of glycans mightbe from partially disordered branched sugar residues. TABLE 1 DataCollection, Structure determination and Refinement Data Collection Dataset Pt peak^(¶) Pt-inflections^(¶) Pt-remote^(¶) Native Space groupP3₁21 Unit Cell (Å) a,b = 111.85, c = 66.34 a,b = 111.26, c = 65.64X-ray source APS Wavelength (Å) 1.0715 1.0718 1.0534 1.100 Resolution(Å) 20-3.85 20-3.85 20-3.85 30-3.32 Observations 49179 50389 45774123640 (uniquely) (8681)^(¶) (8645)^(¶) (8566)^(¶) (7127) I/σ overall16.0 (3.1)* 15.2 (3.3)* 13.2 (2.3)* 17.3 (37)* Completeness (%) 99.2(91.8)* 99.6 (96.3)* 97.6 (82.9)* 99.7 (100.0)* R_(Merge) (%)  7.5(45.4)*  6.9 (42.3)*  8.0 (55.4)*  7.3 (37.1)* Structure DeterminationFigure of Merit 0.49 Phasing power 1.92 1.86 1.79 R_(Cullis) (anomalous)0.82 0.84 0.88 R_(Cullis) (isomorpous) 0.60 0.61 0.61 StructureRefinement Resolution (Å) 15-3.32 Number of work/test reflections6144/754 Nonhydrogen protein/carbohydrate/solvent atoms 1692/81/26R_(Work)/R_(Free) (%) 29.5/32.9 Bond length(Å)/angle(°) rms deviationfrom ideal geometry 0.011/2.325 Ramachandran statistics (%)68.5/23.4/8.2/0 Favourable/Additional/Generous/Forbidden Protein atomsaverage B value (Å²), Mainchain/Sidechain 55.12/64.15

EXAMPLE 4 Molecular structure of msCEACAM1a[1,4]

[0082] The msCEACAM1a[1,4] protein analyzed contains the 202extracellular amino acids of the naturally expressed CEACAM1a[1,4]protein plus a six histidine-tag connected to the carboxy-terminus by athrombin cleavage peptide. This soluble murine CEACAM1a[1,4] protein hasstrong virus neutralization activity at 37 ° C., pH 7.2, and readilyinduces an irreversible conformational change in the MHV-A59 spikeglycoprotein under these conditions (Zelus et al., 1998).

[0083]FIG. 1 shows the ribbon diagram of the molecular structure ofsoluble murine msCEACAM1a [1,4]. The two Ig-like domains ofmsCEACAM1a[1,4] are arranged in tandem. When the membrane proximaldomain (D4) was oriented vertically as if it were perpendicular to thecell membrane, the virus-binding domain (D1) had a bending angle ofabout 60° from the vertical, with its A′GFCC′C″ β sheet (called CFG facehereafter) facing upwards, away from the cell membrane (FIG. 1). Therotation angle between D1 and D4 is about 170°, which places the CFGface of D4 on the opposite side of the molecule from the CFG face of D1,Other IgSF proteins on the cell surface have this orientation (Wang andSpringer, 1998). Although there are five potential N-linkedglycosylation sites on this protein, the crystal structure showed thatonly four of these sites are utilized: three in D1, and one in D4. Oneor more sugar moieties were clearly seen at each of these sites (FIG.1), but no electron density was visible to indicate the presence of apossible glycan at Asn161 in the Asn-Asn-Ser motif in the DE loop of D4.The only observed glycan in D4 is at Asn119 (FIG. 1) near the bottom ofthe molecule, pointing downward toward the cell membrane. This glycanmay play a role in holding the rod-like molecule erect on the membraneas shown for CD2 (Jones et al., 1992), ICAM-2 (Casasnovas et al., 1997),and CD4 (Wu et al., 1997).

[0084] The N-terminal domain (D1) of msCEACAM1a[1,4] belongs to the Vset Ig-like fold. Within the IgSF, the CEA family and the CD2 family areunique in that their N-terminal domains lack the inter-sheet disulfidebond between β strands B and F that is conserved in the N-terminaldomains of other IgSF members. In the DALI search for structureshomologous to D1 of msCEACAM1a[1,4] using the web site(http://www2.ebi.ac.uk/dali/), D1 of CD2 was one of the top hits. Thereare, however, three important structural elements that distinguish D1 ofmsCEACAM1a[1,4] from CD2-D1. One striking feature of D1 ofmsCEACAM1a[1,4] is its uniquely structured, prominently protruding CC′loop (highlighted in FIG. 1) that points upwards. The unique andintricate structure of the CC′ loop will be described in detail below.D1 of msCEACAM1a[1,4], like other V set Ig-like folds, retains a saltbridge between an arginine (Arg64) at the beginning of the D strand andan aspartate (Asp82) at the beginning of the F strand. This salt bridgemay help to strengthen the interactions between the two anti-parallel βsheets of D1. By contrast, CD2-D1 does not have a salt bridge betweenthe D sheets (Jones et al., 1992). Another difference between the D1s ofmsCEACAM1a[1,4] and CD2 is found at the A-A′ kink. As a structuralhallmark in both V set and I set Ig folds, the A strand in one sheetruns midway through the domain, and then crosses over to join theopposite sheet, becoming the A′ strand. This may stabilize themembrane-distal domain that is usually the site for ligand binding (Wangand Springer, 1998). The amino acid at the kink position is usually acis-proline. In D1 of msCEACAM1a[1,4], the A′ strand is significantlyshorter than that of most other Ig-like molecules, whereas D1 of CD2 andsome other CD2 family members have a relatively long A′ strand with no Astrand at all. These features might reflect differences in thebiological functions of CD2 and CEACAM1a.

[0085] Structural analysis shows that the C-terminal domain (D4) ofmsCEACAM1a[1,4] falls into the I1 set category (Harpaz and Chothia,1994; Wang and Springer, 1998), rather than the C2 set as widelythought. Compared to the I set Ig-like domains of most other IgSFmembers, D4 of msCEACAM1a[1,4] has an unusually long CD loop of 10residues (amino acids 146-155). The long CD loop in D4 ofmsCEACAM1a[1,4] is probably quite stable because it has a β-turn at eachend (including the 2 residue C′ strand) and Leu152 and Leu152 in themiddle of the loop point inward, joining the molecule's hydrophobiccore.

[0086] msCEACAM1a[1,4] has a linker between D1 and D4. The last residueof D1 is His107, and the A strand of the following domain D4 starts atPhe114. The peptide segment in between does not appear to havemainchain-mainchain hydrogen bonds to the D4 domain. No significantinteractions were observed between D1 and D4. The surface buried areabetween these two domains is 530 Å², with a 1.7 Å probe. Theseobservations indicate that the D1-D4 junction of msCEACAM1a[1,4] isquite flexible.

EXAMPLE 5 The unique CC′ loop of the N-terminal Domain Is an MHV-bindingSite

[0087] Both the spike glycoprotein of MHV virions and MAb-CC1, amonoclonal antibody to murine CEACAM1a that blocks the binding of thevirus to the receptor, were shown to bind to D1 of murine CEACAM1a(Dveksler et al., 1993b). Mutational analyses of murine CEACAM1a showthat the peptide segments between amino acids 38 and 43 (Rao et al.,1997) or between amino acids 34 and 52 (Wessner et al., 1998) areinvolved in binding to the MHV spike glycoprotein, in virus receptoractivity and binding of MAb-CC1. The structure for msCEACAM1a[1,4]defined in the present invention shows that this virus binding region isin the CC′ loop and the C′ strand.

[0088] Compared to the N-terminal domains of other IgSF members, D1 ofmsCEACAM1a[1,4] has an unusual CC′ loop, as marked in FIG. 1. Thisstructure could not have been predicted based on the knowledge of theamino acid sequence in this region. FIG. 2A shows an overlay onto D1 ofmsCEACAM1a[1,4] of the N-terminal domains of three other representativeIgSF proteins, CD2 (Jones et al., 1992), CD4 (Wang et al., 1990), andBence-Jones protein REI (Epp et al., 1975), a typical variable domain ofan antibody. The N-terminal domains of both CD2 and CD4 have shorter CC′loops than that of msCEACAM1a[1,4] and REI. Although the CC′ loops of D1of REI and msCEACAM1a[l,4] are the same length, that of REI is onlyslightly curved, while the CC′ loop of msCEACAM1a[1,4] remarkably foldsback onto the CFG face.

[0089] The convoluted conformation of the CC′ loop in D1 ofmsCEACAM1a[1,4] is unique among IgSF molecules. The loop, from Lys35 toGlu44, is well structured (FIG. 2B) and probably maintained in a rigidconformation. Within the C terminal portion of the loop (residues 40 to44), two mainchain hydrogen bonds form one and a half turns of a 3₁₀helix. On the N-terminus of the CC′ loop, Thr38 forms a hydrogen bondwith the carbonyl oxygen of Lys35. The mid portion of the CC′ loop makesclose contact with the CFG face in two ways (FIG. 2B). Particularlyinteresting is the packing of two consecutive planar peptide groups onthe loop, Thr39-Ala40 and Ala40-Ile41, against the aromatic ring ofTyr34 on the C strand. In addition, a bidentate hydrogen bond from theside-chain of Glu44 to side-chains of this Tyr34 and Arg47 helps to holdthe aromatic ring in place for its interactions with the peptide groups.An additional hydrogen bond between the sidechains of Thr39 and Arg96would also hold the CC′ loop toward the β sheet. Although a tyrosineequivalent to Tyr34 is conserved in the variable domains of mostantibody light chains, nevertheless the CC′ loop in antibodies assumes aβ hairpin structure (see REI in FIG. 2A) probably because the conservedPro-Gly sequence motif of antibodies (FIG. 2A) favors a sharp turn atthe tip of the loop. This might prevent the CC′ loop of REI fromassuming a convoluted conformation like that seen in D1 ofmsCEACAM1a[1,4].

[0090] In D1 of msCEACAM1a[1,4], the consequence of the folding back ofthe highly structured CC′ loop against the CFG face is to cause thesidechain of Ile41 at the center of the loop to be prominently exposed,pointing away from the membrane (FIGS. 1 and 2A). Mutational evidencesuggests that the Thr38-Thr39-Ala40O-Ile41 sequence motif in murineCEACAM1a[1,4] is important for binding to the MHV spike glycoprotein(Wessner et al., 1998). Two glycans, one at Asn37 and the other atAsn55, flank this important virus-binding motif (FIGS. 1 and 2B), whichmight help delineate the region for viral spike glycoprotein docking.Based on the structural data presented here, Ile41 is considered to bethe energetic “hot spot” for binding to the MHV spike. A widely acceptedmodel for the interaction of cell surface receptors with their ligandsis that a central hydrophobic contact provides the major binding energy,while surrounding hydrophilic interactions contribute the specificity ofbinding (Clackson and Wells, 1995). This also appears to be the case forreceptor/virus interactions as shown for binding of gp120 glycoproteinof HIV-1 to CD4 (Kwong et al., 1998). FIGS. 2B and 2C show a viewlooking from above down upon the CFG face of D1 of msCEACAM1a[1,4] whichis likely to be the surface accessible to the MHV virus spike protein.The protruding hydrophobic Ile41 is surrounded by a number ofsurface-exposed charged residues, including Asp42, Glu44, Arg47, Asp89,Glu93, and Arg97. Ile41 might insert into a hypothetical hydrophobicpocket in the viral spike glycoprotein, and charged residues thatsurround the pocket could stabilize the MHV binding interaction andcontribute to virus binding specificity. No structures are yet availablefor any coronavirus spike glycoproteins. Strains of MHV that differ invirulence and tissue tropism show considerable variation in the aminoacid sequences of their S glycoproteins, yet all MHV strains tested canuse murine CEACAM1a as a receptor. The observation that there is nosingle anti-S MAb that blocks infection by all strains of MHV (Talbotand Buchmeier, 1985) supports the idea that murine CEACAM1a may bind toa conserved pocket in S that is not accessible to antibody. Theprotruding Ile41 and the charged residues that surround it on thesurface of the virus receptor are targets for further mutationalanalyses.

[0091] Cell adhesion molecules might be particularly suitable candidatesfor virus binding because their physiologic ligand/receptor bindingaffinities are very low, and adhesion is an avidity driven process.Uniquely exposed surface features of the cell adhesion molecules areselected for virus binding. FIG. 3 compares the virus-binding domain ofmsCEACAM1a[1,4] with those of several other virus receptors with the keyvirus-binding elements highlighted. The projecting Ile41 on the uniqueCC′ loop of D1 of msCEACAM1a[1,4] is the key topological feature for MHVbinding. In CD4, the key HIV gp 120-binding Phe43 is located at theprotruding ridge-like C′C″ corner of D1 (Wang et al., 1990). Thisstructural element inserts into a recess in the surface of HIV gp 120(Kwong et al., 1998). Compared to most IgSF members, ICAM-1, thereceptor for the major group of rhinoviruses, has a uniquely taperingtip that inserts into the narrow “canyon” on the rhinovirus surfacewhere the conserved receptor-binding epitopes lie hidden from immunerecognition (Kolatkar et al., 1999). The measles virus receptor CD46belongs to the complement control protein (CCP) superfamily. The centerof the virus-binding epitope of CD46 is a well-structured, protrudingDD′ loop consisting of a small group of hydrophobic residues with thekey Pro39 extending furthest out (FIG. 3) (Casasnovas et al., 1999).Thus, uniquely protruding hydrophobic residues on cell adhesionmolecules might be prime targets for virus binding.

EXAMPLE 6 MHV receptor activities of murine CEACAM isoforms, chimerasand mutants

[0092] The various natural isoforms of the murine CEACAM1a, CEACAM1b andCEACAM2 glycoproteins differ markedly in their virus binding,neutralization and virus receptor activities (Dveksler et al., 1993a;Gallagher, 1997; Ohtsuka et al., 1996; Zelus et al., 1998). A series ofsoluble or anchored mutant murine CEACAM proteins with various pointmutations, deletions, or domain exchanges with other CEA-relatedglycoproteins has been tested for virus binding and receptor activities(Rao et al., 1997; Wessner et al., 1998). Several observations weremade. MHV-A59 and soluble spike protein bound better to D1 of murineCEACAM1a from MHV susceptible mice than to CEACAM1b from MHV-resistantmice. Soluble murine CEACAM1b[1-4] had 4 to 10 fold less virusneutralization activity for MHV-A59 than msCEACAM1a[1-4]. ThemsCEACAM1b[1-4] failed to neutralize the neurotropic JHM strain of MHV,and msCEACAM1b[1,4] failed to neutralize either MHV-A59 or MHV-JHM(Zeluset al., 1998). While the naturally occurring 2 domain CEACAM1a[1,4]isoform neutralized MHV-A59 nearly as well as the 4 domain isoformCEACAM1a[1-4], a carboxyl terminal deletion protein consisting of D1 andD2 (CEACAM1a[1,2]) had only minimal MHV-A59-neutralizing activity. Thus,there is virus strain specificity in the interactions of MHV withvarious CEACAM1 proteins, and regions of CEACAM1 outside of thevirus-binding domain (D1) can affect virus-receptor activity.

[0093] The amino acid sequences of murine CEACAM1a and CEACAM1b differ,principally in the N-terminal, virus-binding domain (Dveksler et al.,1993a). The lengths of the 1a and 1b proteins are the same, and all ofthe structurally important residues are the same or similar. The overallfolding of murine CEACAM1b isoforms is therefore believed to be the sameas or similar to that of the corresponding CEACAM1a isoforms. FIG. 4A(upper panel) shows the sequence alignment of D1 from murine CEACAM1aand CEACAM1b with β strands underlined. The most extensive differencesbetween CEACAM1a and 1b are in the peptide segment from thevirus-binding CC′ loop to the end of the C″ strand. In D1 of CEACAM1b,residue Ile41 is replaced by a threonine, which may account for its lowvirus binding activity relative to CEACAM1a.

[0094] Without the important Ile41, the question explored was why canmurine CEACAM1b[1-4] serve as an MHV receptor. Comparison of thesequences in the CC′ loop region of D1 of CEACAM1a and 1b (FIG. 4A,upper panel) reveals two differences worthy of particular attention.Both Ile41 (Thr41 in CEACAM1b) and Thr39 (Val in CEACAM1b) areprominently exposed in the CC′ loop (FIG. 2B). In CEACAM1b, Pro38replaces Thr38 of CEACAM1a and may change the conformation of the CC′loop in CEACAM1b so that the projecting Val39 might serve as avirus-binding hotspot as Ile41 does for CEACAM1a, though to a lesserextent. Moreover, CEACAM1b lacks the glycosylation site at Asn37 ofCEACAM1a due to the replacement of the N37TT sequence motif in CEACAM1awith N37PV. These differences in amino acid sequence and glycosylationprobably also affect how spike proteins from various MHV strains dock onthe different CEACAM receptor proteins, resulting in differences inreceptor utilization, tissue tropism and virulence among the virusstrains.

[0095] The carboxy-terminal deletion mutant msCEACAM1a[1,2] has verylittle virus neutralization activity, while the soluble form of thenaturally occurring murine CEACAM1a[1,4] isoform neutralizes virus aswell as the msCEACAM1a[1-4] isoform (Zelus et al., 1998). Analysis ofthe sequence alignment of domains 2 (D2) and 4 (D4) of CEACAM1 a revealstwo major differences (FIG. 4B, upper panel). The BC loop of D2 is tworesidues longer than that of D4, and D2 has four more potentialN-glycosylation sites than D4 (marked with * in FIG. 4B). The longer BCloop of D2 and the possible glycan attached to Asn192 at the beginningof the G strand of D2 may both restrict inter-domain flexibility betweenD1 and D2 in msCEACAM1a[1,2] in comparison to the junction between D1and D4 in msCEACAM1a[1,4]. Moreover, the present invention modelbuilding suggests that there is a hydrogen bond between His 107 of D1and Asn141 of D2, while no such hydrogen bond is possible at this sitein the junction of D1 and D4. All of these structural differences couldcause the D1-D2 junction to be less flexible than the highly flexiblejunction between D1 and D4 revealed by X-ray crystallography. InCEACAM1a[1,2] on the cell membrane, the limited flexibility at the D1-D2junction might make it more difficult for a virus to attach. The fourdomain isoform CEACAM1a[1-4] has two more interdomain junctions than thetruncated CEACAM1a[1,2] protein, and may therefore be more flexible.

EXAMPLE 7 Predicted Structures of CEA Family Members and Conservation ofGlycan-Shielded Surface Hydrophobic Patch in the N-terminal Domain

[0096] CEA family members are all composed of several Ig-like domains intandem. Following the N-terminal domain, two similar types of domains,called A and B, alternate along the chain. For example, CEA (CD66e),encoded by the CEACAM5 gene, has the N-A1-B1-A2-B2-A3-B3 domainstructure (Hammarstrom, 1999).

[0097] Blast search (http://www.ncbi.nlm.nih.gov/BLAST/) of D1 of murineCEACAM1a found sequences of N-terminal domains of all mammalian CEAmembers. Five residues appear to be absolutely conserved: Trp33, Arg64,Leu73, Asp82 and Tyr86 (FIG. 4A, lower panel). No significant deletionsor insertions were found in D1 of human CEA-related proteins, except fora few cases in which the length of the C′C″ loop varied slightly. LikeD1 of murine CEACAM1a, the N-terminal domains of all members of the CEAfamily shown in FIG. 4A can be classified as V set Ig-like fold (Bateset al., 1992). This is determined by these key conserved structuralfeatures (Chothia et al., 1998): Pro8 at the A-A′ kink point; Trp33 onthe C strand that acts as the center of a hydrophobic core; a saltbridge between Arg64 and Asp82; and the tyrosine-corner motif(Hemmingsen et al., 1994) D*G*Y86 at the beginning of the F strand.

[0098] One of the newly recognized, highly conserved structural featuresof msCEACAM1a[1,4] that appears to be unique to CEA family members(listed in FIG. 4A) is the glycosylation site at Asn70, on the oppositeside of D1 from the proposed virus-binding surface (FIG. 1). In thecrystal structure of msCEACAM1a[1,4], the glycan at Asn70 is betterordered than other glycans. Beneath the presumably large glycan at Asn7Olies a group of hydrophobic residues, including Val7 and Pro8 of the Astrand, Leu18 and Leu20 of the B strand, Leu74 of the E strand, andprobably also Tyr68 and Ile66 of the D strand. The area covers about 650Å². The glycan at Asn70 appears to stabilize the protein by preventingthe exposure of this large surface hydrophobic patch. Most of theseprotected amino acid residues are either invariant (Pro8 and Leu18) orvery conserved (Leu20, Tyr68 and Leu74) among CEA proteins (FIG. 4A).This is the first example of a three-dimensional structure consisting ofa large, glycan-shielded surface hydrophobic patch that is conserved ina protein family. This structural feature is believed to have biologicalsignificance in the CEA family.

[0099] To assess the pattern of sequence conservation for all members ofthe mammalian CEA family in the SWISSPROT database, the variability insequence using Shannon's entropy (Stewart et al., 1997) was calculated.FIG. 5 shows a topology diagram of D1 of msCEACAM1a[1,4] coded toindicate the relative degree of conservation of residues calculated for42 CEA family members. A striking difference was discovered in theextent of amino acid conservation between the two faces of D1 among CEAfamily members. The ABED face containing the glycan-shielded hydrophobicpatch is much more conserved than the CFG face. The CFG faces of theN-terminal domains of IgSF proteins are frequently used for cell surfacerecognition (Stuart and Jones, 1995; Wang and Springer, 1998). Thevariability in this face among CEA members is considered to be used forbinding specificities.

[0100] In the lower panel of FIG. 4B, the sequences of the six A and Btype domains of the human CEA protein are aligned with D2 and D4 ofmurine CEACAM1a. The three A type domains of human CEA, and probably theA domains of other CEA members as well, are structurally very homologousto D4 of murine CEACAM1a, an II set of Ig-fold. The B type domains ofhuman CEA appear to have no D strand, but probably a C′ strand thatdirectly connects to the E strand, as observed for 12 set of Ig-fold(Wang and Springer, 1998). Both I1 and I2 sets differ from the C set byhaving the A-A′ kink, and they are distinct from the V set in not havingthe C″ strand (Wang and Springer, 1998). In summary, data suggest thatthe general architecture of all CEA family members consists of a V setN-terminal domain followed by alternating I1and I2 set Ig-like domains.

EXAMPLE 8 The CC′ and FG Loops of the N-terminal Domains of Various CEAFamily Members Play a Role in the Mediation of Biologically ImportantMolecular Interactions

[0101] The structure of murine CEACAM1a can be used to elucidate othermolecular interactions of CEA family members including bacterialbinding, immunomodulation, and homophilic and heterophilic adhesion.

[0102] Certain human CEA family members are subverted as receptors forbacterial pathogens including Hemophilus influenzae, Neisseriameningitidis and Neisseria gonorrhoeae. The N-terminal domains of manyhuman CEA members are recognized by multiple Opa (opacity-associated)proteins on the surface of pathogenic strains of Neisseria (Bos et al.,1999; Virji et al., 1999). Homologue scanning mutagenesis revealed thatPhe29, Ser32 and Gly4l (and to a lesser extent Gln44) of CEA (CD66e) arerequired for maximal Opa protein binding activity (Bos et al., 1999).Tyr34 and Ile91 (and to a lesser extent Val39 and Gln89) of humanCEACAM1 (CD66a) are critical residues for most Opa protein interactions(Virji et al., 1999). Since the N-terminal domains of CEA and humanCEACAM1 are the same length as that of murine CEACAM1 a (FIG. 4A), FIG.2B was used to show that the Neisseria-binding residues on CEA and humanCEACAM1 are on the C strand through the CC′ loop and on the F strand.Val39 and Gly41 of human CEACAM1 and CEA, respectively (corresponding toThr39 and Ile41 in msCEACAM1a[1,4], FIG. 2B) are on the tip of the CC′loop. If the CC′ loops of CEA and CEACAM1 were as flat as that of theBence-Jones protein REI (FIG. 2A), then Val39 and Gly41 would not beclose enough to other important Opa-binding residues to form anintegrated binding site. This may explain why the Y34A mutation of humanCEACAM1 abrogated binding of the majority of Opa proteins (Virji et al.,1999), since the aromatic ring of this conserved Tyr34 is the key tomaintaining the convoluted structure of the CC′ loop as shown formsCEACAM1a[1,4]. Thus, the CC′ loops of CEA and human CEACAM1 probablyassume a convoluted conformation like that of msCEACAM1a[1,4]. Thesecond point is that the area around Phe29 of CEA and Ile91 of humanCEACAM1 (corresponding to Gly29 and Thr91 in msCEACAM1a[1,4], FIG. 2B)is highly hydrophobic and might be an important determinant of bindingenergy. Knowing the structure of msCEACAM1a[1,4] makes it possible torationally design mutations to elucidate the molecular basis of thespecific interactions between bacterial Opa proteins and CEA members onhuman cell membranes. Based on the CEACAM1 structure, it is possible todesign small molecules that can interfere with binding of ligands to thebiologically important CC′ loop of CEACAM1 or related CEA familymembers.

EXAMPLE 9 Molecular Mechanism of PSG's Function in Pregnancy

[0103] The pregnancy-specific glycoprotein (PSG) subfamily of the CEAfamily appears to be essential for a successful pregnancy, although thefunctions of PSGs are not yet fully understood. PSGs may attenuate themother's immune response to her semi-allogeneic fetus (Hammarstrom,1999). The N-terminal domains of most human PSGs, but not baboon orrodent PSGs, contain an Arg-Gly-Asp (RGD) motif. The RGD motif is knownto be associated with integrin binding and mediates a wide variety ofcell adhesion events. For example, in human fibronectin (FN), anintegrin-binding RGD motif is located on a type I′ turn at the tip of aprotruded FG loop of the 10^(th) FN domain (Leahy et al., 1996). FIG. 4Ashows that in D1 of the human PSGs the RGD motifs are aligned at thevery tip of the FG loop (highlighted in violet in FIG. 1). Thecorresponding sequence in msCEACAM1a[1,4] is Glu92-Asn93-Tyr94 (FIG.4A), which assumes a type II β turn. Those PSG proteins with an RGDmotif can slightly change the conformation at the tip of the FG loop toadopt a type II′ turn more suitable for integrin binding. Theheterophilic binding of soluble PSGs to integrins might cause localimmunosuppression in the uterus by shielding the integrins on cellmembranes (Hammarstrom, 1999). In other species, PSGs lacking the RGDmotif may still use one acidic residue (Glu or Asp) in the protruding FGloop (Zhou and Hammarstrom, 2001) to bind integrin, as demonstrated forleukocyte integrin ligands (Wang and Springer, 1998) and E-cadherin(Taraszka et al., 2000).

[0104] Knowing the molecular mechanism of PSG's function will be used indrug design for pregnancy-associated problems.

EXAMPLE 10 The CC′ Loop of Domain 1 of CEACAM1 May Also MediateHomophilic Cell Adhesion

[0105] CEA family members can mediate intercellular adhesion in vitroand in vivo through binding interactions that involve the N-terminaldomain (Hammarstrom, 1999). Mutational analyses of the N-terminal domain(D1) of human CEACAM1 and CEA showed that residues on the CFG face, andespecially residues on the CC′ loop of D1 are directly engaged inhomophilic cell adhesion. Mutations V39A and D40A in the CC′ loopabolished homophilic adhesion of human CEACAM1.

[0106] To study mechanisms for homophilic binding of msCEACAM1a[1,4],the molecular interactions observed in the crystal lattice ofmsCEACAM1a[1,4] were examined. Two major contact areas betweensymmetry-related molecules were found, one through D1 by a 2-fold axis,and the other through D4 by a 3-fold axis. The D1 -D1 contact seems mostinteresting. FIG. 6 shows how the CC′ and FG loops in D1 s of twodyad-related molecules made contact in the crystal structure ofmsCEACAM1a[1,4]. Hydrophilic interactions appear to dominate theadhesive interface, like that between CD2 and CD58 (Wang et al., 1999).However, the D1-D1 contact seen in FIG. 6 is quite different from theanti-parallel “hand-shaking” mode of CD2/CD58 interactions via theirrelatively flat CFG faces. For several reasons, the more “parallel” modeof homophilic D1-D1 contact seen between msCEACAM1a proteins areconsidered by the present inventors to be of physiological significance.First, as discussed above, the uniquely convoluted conformation of theCC′ loop of msCEACAM1a[1,4] is likely to be similar for human CEAmembers. The fact that Y34A, but not Y34F, mutation abrogated homophilicadhesion of CEA (Taheri et al., 2000) shows the importance of thehydrophobic aromatic ring for maintaining the structure of theconvoluted CC′ loop. A convoluted, protruding CC′ loop would likelyprevent CEA molecules from adopting the “hand-shaking” type of adhesionseen between CD2 and CD58. FIG. 6B shows that Val39 of one human CEACAM1molecule (corresponding to Thr39 in msCEACAM1a[1,4]) might havehydrophobic contact with Val39 from its symmetry-mate, while Asp40 ofCEA (corresponding to Ala40 of msCEACAM1a[1,4], FIG. 6B) mightpotentially form a salt bridge with Arg38 from the symmetry-mate. Thismay explain why mutations V39A and D40A in CEACAM1 disrupt homophiliccell adhesion.

[0107] The “parallel” mode of adhesion could occur between molecules onthe same cell or opposing cells. The numerous inter-domain junctions oflong CEA members may render them flexible enough to permit atrans-interaction between opposing cells using this “parallel” mode. CHOcells transfected with human CEACAM1-1s, which has only the D1 domain asits extra-cellular portion, showed negligible adhesion despite a highlevel of protein. Not enough flexibility in this short moleculeprohibited this “parallel” mode of binding. Further crystallographicstudies and mutational analysis are needed to characterize cis- ortrans-adhesion mechanisms between CEA family members.

EXAMPLE 11 Extrapolating the Murine CEACAM1 Structure Onto HumanHomologues Using Molecular Modelling

[0108] The X-ray structure of msCEACAM1a[1,4] can be used as a templatefor the reconstruction of the three-dimensional structure of humanhomologues of the CEA family. The sequence homology between mouseCEACAM1a[ 1,4] and its homologues is high. For example, the sequenceidentity of the N-terminal domains (D1) between msCEACAM1a and humanCEACAM1 is greater than 30%, which allows building of models of humanCEA family members as benchmarks for structure based drug design. Inaddition, the molecular architecture of the murine and human homologuesis highly similar. Most human homologues have a similar number ofresidues, especially in D1, in which the ABDE beta sheet is highlyconserved. Like msCEACAM[1,4], of all human homologues D1 lack adisulfide bridge typical for most Ig domains, and the murine and humanhomologues share a salt bridge that keeps the two beta sheets together.

[0109] The models of the two N-terminal domains of human homologues(CEACAM1, CEACAM5 and CEACAM6) were constructed through substitution ofthe residues in the msCEACAM[1,4] structure by their counterparts foundin the respective human sequence. The resulting model is subjected toenergy minimization to improve the atomic contacts and obtain achemically sensible model. The homology modelling can be done withprograms such as Modeller (A. Fiser, R. K. Do & A. Sali Protein Science9. 1753-1773, 2000).

EXAMPLE 12 Monoclonal Antibody Mapping of CEA Molecules

[0110] With the structure of msCEACAM1a[1,4] available, and given thehigh degree of sequence and structure homology between D1 of mouseCEACAM1a and human CEA family members, a model of the first two domains(N-A1) of human CEA (gene product of CEACAM5) and NCA was constructed bysimply making amino acid replacements on msCEACAM1a[1,4] for CEA. Sincesequences of CEA and CEACAM6 are 90% and 84% identical in theirN-terminal domain and A and B type domains (Hefta, et al.), the modelcould also be used for human CEACAM1 (BGP) and CEACAM6 (NCA) with minorchanges. GOLD Mabs are known to have their epitopes on protein, but noton carbohydrates (Hammarstrom, et al., (1989). Glycosylation sites onCEA and CEACAM6 were used to delineate the possible epitope area, byassuming that residues located within 6A from the glycosylation sitesare excluded from access by any antibody. FIG. 7 is the surfacerepresentation of the model, in which the glycan-protected areas for CEAis a cross-hatched area, labeled (I). The area shielded by glycans onCEACAM6 but not on CEA is labeled (II). The white areas are exposed andthey contain the potential Mabs epitopes that recognize both CEA andCEACAM 6. The white areas are exposed and they contain are the potentialMabs epitopes that recognize both CEA and CEACAM6 except for a fewresidues substitution between these two molecules, which could differ insome cases. The large white area on the N-terminal domain is on the CFGface, on which many of GOLD 5 Mabs bind. These Mabs cross-react withCEACAM6 (Murakami, et al. (1995)). On the Al domain of CEA/CEACAM6, thearea labeled (III) contains the large and protruded CD loop whereas thearea labeled (IV) contains the A-A′ strands plus part of the G strand.These are likely to be the locations of epitopes of cross-reacting Mabsin the GOLD 4 group, which bind to A1-B1 domains (Murakami, et al.,(1995)). The area labeled (II) is most interesting. This is the regionspanning the BC and FG loops of domain A1 which is covered by glycansthat only exist in CEACAM6. A region like this should be a goodcandidate to develop CEA-specific Mabs that do not recogize CEACAM6.Further modeling efforts are needed to aid the development ofsite-specific anti-CEA monoclonal antibodies for future medical use maybe created using this modeling approach.

EXAMPLE 13 Drug Screening for Anti-Viral, Anti-Inflammatory andAnti-Cancer Agents

[0111] The present example is provided to demonstrate the utility of thepresent invention for the selection and screening of a variety ofcandidate substances for anti-viral, anti-bacterial, anti-inflammatory,immunomodulatory and anti-cancer activity.

[0112] The target control molecule that will be used is the solublecarcinoembryonic antigen (CEACAM1a[1,4]), described herein. The agentthat will be used to quantify binding activity of a candidate substance,and against which the relative acceptability of a candidate substancewill be determined, will be, by way of example, a monoclonal antibody.One such monoclonal antibody, CC1, antibody to the CC′ loop of mouseCEACAM1a is described in Wessner at al. (1998) which reference isspecifically incorporated herein by reference. In general, substances(i.e., a candidate substance) that are capable of a binding specificallyto the CC′ loop of mouse CEACAM1 having the unique conformationalcharacteristics identified here with an binding affinity in the range of104 to 1010 will be selected for use as potentially suitable anti-viral,anti-inflammatory immunomodulatory, and/or anti-cancer agents.

[0113] It should be understood that other monoclonal and polyclonalantibodies, or other types of molecules, that posseses the same orrelatively the same binding affinity for the novel structure of the CC′loop of mouse or human CEACAM1 protein as described here may also beused in the practice of the method for selecting candidate substancessuitable for the uses described here.

[0114] It is expected that the disclosed method will be useful inidentifying agents that may be used in the treatment and therapy ofhumans using the identified functional domain of CEACAM1 identified hereas the CC′ loop because of the high degree of structural similarity thatthe present investigators have inferred from mutational data as existingbetween the sequenced CC′ region of mouse and human CEACAM1a. Thisregion possesses about 10 amino acids in the mouse and the humansequences which are compared below, along with the amino acids thatstabilize the uniquely structure of the CC′ loop:

[0115] Mouse CC′ region—-K G N T T A I D K E-(SEQ ID NO: 3)

[0116] Important amino acids that stabilize the structure of the CC′loop:

[0117] Y34, E44, R47, R96 and possibly D89

[0118] Human CC′ region—-K G E R V D G N RQ-(SEQ ID NO: [2]1)

[0119] Amino acids that likely stabilize the structure of the CC′ loop:

[0120] Y34, Q44, G47, and Q89

[0121] It is envisioned that the unique convoluted structure of this CC′loop will be used to develop an algorithm that will provide athree-dimensional (3-D) blueprint of structure against which candidatesubstances can be identified and compared as likely to attach to thefunctional CC′ loop of D1. This will then be incorporated into asoftware program wherein the calculation and identification of likelysuitable candidate substances can be screened automatically and at arelatively rapid rate. Software programs currently available in the artfor the purpose of drug screening and selection may be found athttp://www.small-molecule-drug-discovery.com/high_screening.html.

[0122] The identified candidate substances that have binding activityfor CEACAM1 as identified here, are also intended as part of the presentinvention. As a further step, and in some embodiments, the selectedcandidate substances may then be examined in an in vitro assay, such asfor ability to bind CEACAM1 protein. Specificity of binding will betested by using CEACAM1 proteins from different species, and otherrelated glycoproteins in the CEA family.

[0123] Alternatively, the candidate substance can be tested for theability to block the binding of a monoclonal antibody such asanti-CEACAM1 Mab-CC1 or the MHV viral spike glycoprotein (S) or ahomophilic region of CEACAM1 to the functional domain CC′ of the CEACAM1protein.

[0124] In yet another approach, the candidate substance may be testedfor its ability to block the binding of MHV to mCEACAM1a, or for theability to block the homophilic interaction of mCEACAM1a.

EXAMPLE 14 Pharmaceutical Preparations for Modulation of DiseasesRelated to Angiogenesis and Tumor Inhibition and Immune Response

[0125] The molecules of the present invention may be selected to providea pharmacologically active preparation that will provide interferencewith aberrant angiogenesis, tumor metastasis inhibition, or otherfunctions such as immunomodulation or virus or bacterial infection(Najajime et al., 2002). Because MAb-CC1 in the circulation inhibitsdelayed type hypersensitivity in vivo (and blocks MHV virus binding toCEACAM1 on murine cells), and virus binds by the CC′ loop, the CC′ loopis an important biological molecule needed for delayed typehypersensitivity in vivo. Inhibiting/blocking this loop on D1 mayprevent delayed type hypersensitivity or other immune mediated damage.This could be used in allergic reactions, autoimmune disorders etc. Theother application for pharmacological uses focuses on the angiogenesisactivity of CEACAM1.

EXAMPLE 15 Drug Screening for Anti-Viral, Anti-Inflammatory andAnti-Cancer Agents

[0126] The administration to infant mice by the intranasal andintraperitoneal routes of monoclonal antibody MAb-CC1 (directed towardthe CC′ loop of murine CEACAM1a) prevents infection and death of theanimals following MHV inoculation (Smith, A. L et al. (1991). Thereforea candidate substance selected according to the present method that istargeted to the CC′ loop of murine CEACAM1a, the receptor for MHV, willbe employed to block, prevent or treat MHV infection of mice in vivo.

[0127] After the previous in vitro tests described above have shown thata candidate CEACAM1a targeted substance can specifically block thebinding of murine coronavirus MHV or its spike glycoprotein (S) to theCC′ loop in the N-terminal domain of murine CEACAM1a, it will bedetermined whether the substance is toxic to a variety of murine cellsin vitro. If it is not toxic, it then will determine whether it is toxicwhen administered to mice by the intranasal, intravenous orintra-peritoneal routes at doses in the range of the observedpharmacologic effect in vitro. If the drug candidate is not toxic invivo, administration of the candidate substance to mice beforeinoculation with MHV by the intranasal or the intraperitoneal routes, orat different times after the virus inoculation. It will then determinewhether the candidate substance will block or reduce virus infection invivo by measuring viral titer in treated vs. control animals in varioustarget tissues such as liver, intestine and spleen. It will then bedetermined whether the substance modulates the immune response to viralinfection by comparing the anti-viral antibody titers from treated vs.untreated animals, as well as by comparing the virus-specificcell-mediated immune responses from treated vs. untreated animals.Comparison of the histopathology, severity of clinical disease andlethal dose₅₀ in the treated vs. untreated animals will also beconducted.

[0128] These methods of using identified candidate substances are ofvalue in preventing or treating MHV infection of mice. MHV is one of themost devastating infections in laboratory mouse colonies because mostinbred mouse strains are highly susceptible to MHV which can modulatetheir immune responses, and cause serious disease or death (S Compton, SBarthold and AL Smith, Lab. Animal Sci. 43:15-28 (1993). When preciousinbred mice become infected with MHV, the colony is sometimes entirelyeuthanized in order to stop the spread of the virus. The animals have tobe re-derived by Ceasarian section and breeding. This causes majoreconomic problems for mouse breeders and university labs that use inbredmouse strains. Sometimes 40,000 mice are destroyed to stop the spread ofMHV in a single colony. Thus a preventive or therapeutic agent for thesekinds of murine dieseases and infecttions are of great potential valuein lab animal husbandry.

EXAMPLE 16 Model Coordinates for CEACAM1a Angiten

[0129] Attached are the coordinates for human CEACAM1, CEACAM5 andCEACAM6 obtained through homology modeling based on the msCEACAM1a[1,4]structure and the respective human sequences. Each model consists of theN and the A1 domain. Further modeling of other human homologues could bedone by the person of ordinary skill provided the disclosure of thepresent invention identifying the crystal structure of the CC′ loop ofCEACAM and/or msCEACAM1a[1,4].

[0130] The following tables set forth the coordinates (X,Y and Z) of theparticular CEACAM molecule indicated:

[0131] Table 2—Full coordinate set of domains N and Al of human CEACAM6(homology model) (1574 Atoms, 203 Amino Acids

[0132] Table 3—Full coordinate set of domains N and Al of human CEACAM 5(homology model)(1606 atoms, 203 amino acids)

[0133] Table 4—Full coordinate set of domains N and Al of human CEACAM1(homology model) (1587 atoms, 203 amino acids)

[0134] Table 5—Full coordinate set of D1 of human CEACAM1a (homolologymodel)

[0135] Table 6—Full coordinate set of D1 D4 of murine CEACAM1a

[0136] Table 7—Coordinate set of CC′ loop of D1 of murine CEACAM1a(partial sequence of #5, corresponding to amino acid positions 35through 45 (atoms positions 264 through 343) TABLE 2 Full coordinate ofdomains N and A1 of human CEACAM6 (homology model) 1574 Atoms, 203 aminoacids) ANum AType RType RNum X Y Z 1 N LYS 1 7.620 28.819 40.444 2 CALYS 1 7.905 27.387 40.250 3 CB LYS 1 6.951 26.553 41.104 4 CG LYS 15.915 27.469 41.747 5 CD LYS 1 4.703 26.772 42.365 6 CE LYS 1 3.49127.698 42.502 7 NZ LYS 1 2.288 26.938 42.909 8 C LYS 1 7.725 26.99438.835 9 O LYS 1 6.819 26.229 38.516 10 N LEU 2 8.639 27.502 37.984 11CA LEU 2 9.103 26.827 36.810 12 CB LEU 2 10.066 25.696 37.214 13 CG LEU2 10.667 24.877 36.062 14 CD2 LEU 2 10.896 23.420 36.495 15 CD1 LEU 211.937 25.546 35.514 16 C LEU 2 7.951 26.253 36.032 17 O LEU 2 7.69425.051 36.091 18 N THR 3 7.233 27.088 35.254 19 CA THR 3 6.437 26.47834.237 20 CB THR 3 4.963 26.343 34.533 21 OG1 THR 3 4.433 27.564 35.01622 CG2 THR 3 4.768 25.228 35.564 23 C THR 3 6.480 27.293 33.004 24 O THR3 7.522 27.690 32.479 25 N ILE 4 5.262 27.478 32.496 26 CA ILE 4 4.92827.361 31.129 27 CB ILE 4 3.441 27.073 31.070 28 CG2 ILE 4 2.837 27.65432.361 29 CG1 ILE 4 2.732 27.535 29.788 30 CD1 ILE 4 1.217 27.551 29.96631 C ILE 4 5.325 28.634 30.477 32 O ILE 4 5.761 29.586 31.119 33 N GLU 55.228 28.668 29.153 34 CA GLU 5 5.422 29.897 28.485 35 CB GLU 5 6.81230.021 27.842 36 CG GLU 5 7.154 31.457 27.466 37 CD GLU 5 8.431 31.40326.658 38 OE1 GLU 5 9.236 30.454 26.855 39 OE2 GLU 5 8.620 32.336 25.83540 C GLU 5 4.417 29.856 27.407 41 O GLU 5 3.651 28.898 27.287 42 N SER 64.387 30.891 26.569 43 CA SER 6 3.765 30.548 25.346 44 CB SER 6 2.22230.411 25.420 45 OG SER 6 1.528 31.438 24.731 46 C SER 6 4.247 31.49324.320 47 O SER 6 4.670 32.612 24.611 48 N THR 7 4.287 30.981 23.079 49CA THR 7 5.042 31.584 22.028 50 CB THR 7 6.325 30.835 21.854 51 OG1 THR7 6.026 29.598 21.215 52 CG2 THR 7 6.952 30.534 23.237 53 C THR 7 4.22931.404 20.763 54 O THR 7 3.463 30.446 20.680 55 N PRO 8 4.309 32.20519.729 56 CA PRO 8 4.811 33.552 19.695 57 CD PRO 8 3.662 31.821 18.48858 CB PRO 8 4.736 34.001 18.221 59 CG PRO 8 4.189 32.792 17.431 60 C PRO8 3.957 34.436 20.558 61 O PRO 8 2.744 34.447 20.363 62 N PHE 9 4.52935.212 21.495 63 CA PHE 9 3.658 36.150 22.147 64 CB PHE 9 4.214 36.76223.434 65 CG PHE 9 5.678 36.533 23.453 66 CD1 PHE 9 6.513 37.198 22.58367 CD2 PHE 9 6.197 35.635 24.356 68 CE1 PHE 9 7.868 36.970 22.605 69 CE2PHE 9 7.550 35.407 24.377 70 CZ PHE 9 8.382 36.072 23.510 71 C PHE 93.392 37.272 21.214 72 O PHE 9 4.251 37.676 20.438 73 N ASN 10 2.16437.799 21.272 74 CA ASN 10 1.665 38.665 20.267 75 CB ASN 10 2.595 39.85119.957 76 CG ASN 10 2.579 40.728 21.207 77 OD1 ASN 10 3.580 40.92421.889 78 ND2 ASN 10 1.366 41.233 21.543 79 C ASN 10 1.449 37.810 19.07480 O ASN 10 2.374 37.187 18.555 81 N VAL 11 0.177 37.723 18.651 82 CAVAL 11 −0.181 36.738 17.682 83 CB VAL 11 −0.986 35.618 18.286 84 CG1 VAL11 −0.901 34.421 17.328 85 CG2 VAL 11 −0.414 35.369 19.702 86 C VAL 11−1.045 37.412 16.678 87 O VAL 11 −1.844 38.281 17.023 88 N ALA 12 −0.91537.024 15.402 89 CA ALA 12 −1.727 37.665 14.416 90 CB ALA 12 −1.01637.845 13.073 91 C ALA 12 −2.914 36.804 14.174 92 O ALA 12 −3.042 35.72114.734 93 N GLU 13 −3.819 37.288 13.312 94 CA GLU 13 −4.962 36.52612.929 95 CB GLU 13 −6.083 37.434 12.420 96 CG GLU 13 −7.442 37.20313.060 97 CD GLU 13 −8.454 37.733 12.071 98 OE1 GLU 13 −9.354 38.49512.515 99 OE2 GLU 13 −8.325 37.384 10.869 100 C GLU 13 −4.531 35.68011.774 101 O GLU 13 −3.760 36.122 10.924 102 N GLY 14 −5.020 34.42911.705 103 CA GLY 14 −4.653 33.582 10.604 104 C GLY 14 −3.280 33.04410.868 105 O GLY 14 −2.676 32.390 10.019 106 N LYS 15 −2.735 33.30412.069 107 CA LYS 15 −1.457 32.727 12.349 108 CB LYS 15 −0.349 33.77212.551 109 CG LYS 15 −0.303 34.737 11.360 110 CD LYS 15 0.972 35.57711.231 111 CE LYS 15 1.888 35.133 10.090 112 NZ LYS 15 2.895 34.19510.623 113 C LYS 15 −1.616 31.908 13.584 114 O LYS 15 −2.574 32.06714.340 115 N GLU 16 −0.675 30.966 13.788 116 CA GLU 16 −0.821 30.01114.840 117 CB GLU 16 −0.146 28.651 14.570 118 CG GLU 16 −0.833 27.77013.527 119 CD GLU 16 0.056 26.561 13.285 120 OE1 GLU 16 −0.486 25.42413.251 121 OE2 GLU 16 1.292 26.760 13.132 122 C GLU 16 −0.148 30.53416.061 123 O GLU 16 0.311 31.672 16.111 124 N VAL 17 −0.095 29.65817.082 125 CA VAL 17 0.547 29.895 18.339 126 CB VAL 17 −0.385 30.39519.393 127 CG1 VAL 17 0.384 30.501 20.724 128 CG2 VAL 17 −1.019 31.71018.916 129 C VAL 17 0.949 28.551 18.811 130 O VAL 17 0.308 27.554 18.485131 N LEU 18 2.024 28.475 19.611 132 CA LEU 18 2.203 27.236 20.295 133CB LEU 18 3.531 26.498 20.034 134 CG LEU 18 3.855 25.454 21.130 135 CD2LEU 18 5.323 25.002 21.059 136 CD1 LEU 18 2.886 24.263 21.131 137 C LEU18 2.184 27.554 21.739 138 O LEU 18 2.708 28.575 22.182 139 N LEU 191.571 26.672 22.528 140 CA LEU 19 1.659 26.907 23.925 141 CB LEU 190.353 26.602 24.665 142 CG LEU 19 −0.698 27.727 24.483 143 CD2 LEU 19−0.663 28.307 23.060 144 CD1 LEU 19 −0.565 28.786 25.585 145 C LEU 192.754 26.028 24.411 146 O LEU 19 2.772 24.832 24.123 147 N LEU 20 3.73726.610 25.120 148 CA LEU 20 4.891 25.843 25.475 149 CB LEU 20 6.19926.632 25.257 150 CG LEU 20 7.433 25.836 24.781 151 CD2 LEU 20 8.72326.681 24.847 152 CD1 LEU 20 7.201 25.276 23.371 153 C LEU 20 4.78125.604 26.935 154 O LEU 20 4.641 26.556 27.698 155 N ALA 21 4.868 24.34027.374 156 CA ALA 21 5.122 24.176 28.767 157 CB ALA 21 4.385 22.99529.407 158 C ALA 21 6.567 23.873 28.824 159 O ALA 21 7.066 23.125 27.989160 N HIS 22 7.309 24.447 29.775 161 CA HIS 22 8.667 24.034 29.806 162ND1 HIS 22 10.587 26.724 28.707 163 CG HIS 22 9.610 26.340 29.597 164 CBHIS 22 9.628 25.070 30.376 165 NE2 HIS 22 9.076 28.349 28.739 166 CD2HIS 22 8.690 27.344 29.599 167 CE1 HIS 22 10.218 27.933 28.227 168 C HIS22 8.701 22.867 30.704 169 O HIS 22 7.928 21.930 30.528 170 N ASN 239.595 22.900 31.701 171 CA ASN 23 9.877 21.734 32.479 172 CD ASN 2311.154 21.879 33.304 173 CG ASN 23 12.285 22.405 32.420 174 OD1 ASN 2312.170 23.411 31.719 175 ND2 ASN 23 13.448 21.705 32.482 176 C ASN 238.752 21.548 33.435 177 O ASN 23 8.089 22.503 33.833 178 N LEU 24 8.51720.287 33.839 179 CA LEU 24 7.381 19.958 34.643 180 CD LEU 24 7.20020.852 35.887 181 CG LEU 24 8.332 20.666 36.915 182 CD2 LEU 24 8.99619.295 36.739 183 CD1 LEU 24 7.841 20.876 38.349 184 C LEU 24 6.16520.082 33.793 185 O LEU 24 5.866 21.201 33.373 186 N PRO 25 5.437 19.02733.465 187 CA PRO 25 5.908 17.659 33.501 188 CD PRO 25 4.903 19.21832.126 189 CB PRO 25 6.720 17.545 32.212 190 CG PRO 25 5.835 18.36031.226 191 C PRO 25 6.501 16.978 34.707 192 O PRO 25 6.691 17.580 35.761193 N GLN 26 6.768 15.666 34.528 194 CA GLN 26 7.442 14.768 35.431 195CB GLN 26 8.104 15.412 36.655 196 CG GLN 26 7.770 14.637 37.932 197 CDGLN 26 7.546 15.632 39.054 198 OE1 GLN 26 8.039 15.419 40.159 199 NE2GLN 26 6.788 16.731 38.780 200 C GLN 26 6.419 13.824 35.976 201 O GLN 265.367 14.276 36.429 202 N ASN 27 6.758 12.502 35.929 203 CA ASN 27 5.90411.337 36.018 204 CB ASN 27 6.414 10.183 36.902 205 CG ASN 27 6.6208.976 35.985 206 OD1 ASN 27 7.602 8.240 36.069 207 ND2 ASN 27 5.6508.775 35.053 208 C ASN 27 4.560 11.698 36.508 209 O ASN 27 4.224 11.51337.677 210 N ARG 28 3.756 12.244 35.587 211 CA ARG 28 2.435 12.62235.934 212 CB ARG 28 1.977 13.863 35.158 213 CG ARG 28 3.065 14.93935.087 214 CD ARG 28 2.884 15.919 33.928 215 NE ARG 28 2.542 17.25534.494 216 CZ ARG 28 2.005 18.198 33.705 217 NH1 ARG 28 1.699 19.44434.191 218 NH2 ARG 28 1.760 17.923 32.373 219 C ARG 28 1.584 11.46535.553 220 O ARG 28 2.039 10.322 35.513 221 N ILE 29 0.306 11.710 35.253222 CA ILE 29 −0.388 10.580 34.747 223 CB ILE 29 −1.260 9.867 35.740 224CG2 ILE 29 −2.564 10.660 35.918 225 CG1 ILE 29 −1.493 8.428 35.259 226CD1 ILE 29 −2.598 7.689 36.021 227 C ILE 29 −1.233 11.043 33.619 228 OILE 29 −1.501 10.281 32.696 229 N GLY 30 −1.678 12.313 33.644 230 CA GLY30 −2.509 12.762 32.570 231 C GLY 30 −2.733 14.221 32.737 232 O GLY 30−2.953 14.725 33.836 233 N TYR 31 −2.667 14.944 31.612 234 CA TYR 31−2.864 16.350 31.711 235 CB TYR 31 −1.821 17.186 30.958 236 CG TYR 31−0.744 16.309 30.393 237 CD1 TYR 31 −0.722 16.108 29.029 238 CD2 TYR 310.222 15.700 31.164 239 CE1 TYR 31 0.235 15.334 28.438 240 CE2 TYR 311.185 14.926 30.573 241 CZ TYR 31 1.195 14.749 29.221 242 OH TYR 312.195 13.952 28.649 243 C TYR 31 −4.198 16.662 31.122 244 O TYR 31−4.862 15.787 30.572 245 N SER 32 −4.625 17.933 31.248 246 CA SER 32−5.796 18.457 30.608 247 CB SER 32 −6.949 18.690 31.606 248 OG SER 32−8.025 19.375 30.976 249 C SER 32 −5.390 19.814 30.131 250 O SER 32−4.558 20.472 30.751 251 N TRP 33 −5.952 20.280 29.007 252 CA TRP 33−5.713 21.650 28.668 253 CB TRP 33 −5.156 21.874 27.250 254 CG TRP 33−3.701 22.239 27.275 255 CD2 TRP 33 −3.205 23.535 27.632 256 CD1 TRP 33−2.612 21.458 27.047 257 NE1 TRP 33 −1.464 22.173 27.279 258 CE2 TRP 33−1.812 23.456 27.637 259 CE3 TRP 33 −3.861 24.690 27.954 260 CZ2 TRP 33−1.046 24.530 27.962 261 CZ3 TRP 33 −3.085 25.776 28.266 262 CH2 TRP 33−1.711 25.701 28.274 263 C TRP 33 −7.035 22.325 28.707 264 O TRP 33−8.024 21.779 28.223 265 N TYR 34 −7.096 23.525 29.302 266 CA TYR 34−8.379 24.122 29.478 267 CB TYR 34 −8.706 24.407 30.947 268 CG TYR 34−9.262 23.141 31.506 269 CD1 TYR 34 −8.704 22.577 32.634 270 CD2 TYR 34−10.331 22.524 30.900 271 CE1 TYR 34 −9.219 21.412 33.151 272 CE2 TYR 34−10.846 21.353 31.425 273 CZ TYR 34 −10.283 20.796 32.548 274 OH TYR 34−10.805 19.596 33.086 275 C TYR 34 −8.395 25.410 28.743 276 O TYR 34−7.661 25.592 27.768 277 N LYS 35 −9.278 26.321 29.190 278 CA LYS 35−9.405 27.603 28.578 279 CB LYS 35 −10.088 27.553 27.203 280 CG LYS 35−10.514 28.929 26.699 281 CD LYS 35 −11.816 28.932 25.895 282 CE LYS 35−12.406 30.329 25.767 283 NZ LYS 35 −12.298 30.806 24.369 284 C LYS 35−10.328 28.384 29.445 285 O LYS 35 −11.493 28.021 29.592 286 N GLY 36−9.841 29.503 30.012 287 CA GLY 36 −10.746 30.468 30.573 288 C GLY 36−10.684 30.405 32.066 289 O GLY 36 −11.575 30.898 32.753 290 N GLU 37−9.611 29.811 32.614 291 CA GLU 37 −9.392 29.823 34.032 292 CB GLU 37−9.649 31.202 34.685 293 CG GLU 37 −9.453 31.230 36.206 294 CD GLU 37−9.914 32.593 36.684 295 OE1 GLU 37 −9.798 32.881 37.905 296 OE2 GLU 37−10.390 33.366 35.814 297 C GLU 37 −10.285 28.820 34.684 298 O GLU 37−9.834 28.041 35.522 299 N ARG 38 −11.579 28.825 34.327 300 CA ARG 38−12.542 27.995 34.986 301 CB ARG 38 −13.915 28.091 34.316 302 CG ARG 38−14.956 27.134 34.870 303 CD ARG 38 −16.265 27.224 34.094 304 NE ARG 38−17.321 27.676 35.055 305 CZ ARG 38 −18.634 27.656 34.660 306 NH1 ARG 38−19.632 27.778 35.587 307 NH2 ARG 38 −18.928 27.459 33.349 308 C ARG 38−12.072 26.581 34.921 309 O ARG 38 −11.723 26.089 33.852 310 N VAL 39−11.995 25.911 36.090 311 CA VAL 39 −11.356 24.629 36.203 312 CB VAL 39−10.620 24.533 37.522 313 CG1 VAL 39 −9.868 23.201 37.613 314 CG2 VAL 39−9.681 25.744 37.595 315 C VAL 39 −12.418 23.557 36.100 316 O VAL 39−12.421 22.573 36.838 317 N ASP 40 −13.345 23.742 35.142 318 CA ASP 40−14.331 22.746 34.831 319 CB ASP 40 −15.718 23.341 34.488 320 CG ASP 40−16.835 22.729 35.328 321 OD1 ASP 40 −18.013 23.021 34.994 322 OD2 ASP40 −16.533 21.985 36.299 323 C ASP 40 −13.840 22.065 33.587 324 O ASP 40−12.978 22.587 32.877 325 N GLY 41 −14.389 20.865 33.306 326 CA GLY 41−14.076 20.140 32.112 327 C GLY 41 −15.274 20.255 31.244 328 O GLY 41−15.424 19.531 30.261 329 N ASN 42 −16.137 21.209 31.627 330 CA ASN 42−17.182 21.794 30.845 331 CB ASN 42 −17.677 23.049 31.598 332 CG ASN 42−18.757 23.863 30.898 333 OD1 ASN 42 −18.943 23.835 29.684 334 ND2 ASN42 −19.505 24.633 31.732 335 C ASN 42 −16.533 22.183 29.551 336 O ASN 42−16.920 21.745 28.469 337 N SER 43 −15.478 23.006 29.621 338 CA SER 43−14.702 23.203 28.442 339 CB SER 43 −14.129 24.608 28.322 340 OG SER 43−13.381 24.697 27.115 341 C SER 43 −13.537 22.292 28.564 342 O SER 43−12.404 22.750 28.704 343 N LEU 44 −13.785 20.968 28.533 344 CA LEU 44−12.666 20.085 28.500 345 CB LEU 44 −12.924 18.633 28.926 346 CG LEU 44−11.588 17.872 29.023 347 CD2 LEU 44 −11.714 16.620 29.910 348 CD1 LEU44 −10.461 18.839 29.421 349 C LEU 44 −12.188 20.048 27.099 350 O LEU 44−12.898 19.637 26.180 351 N ILE 45 −10.946 20.520 26.926 352 CA ILE 45−10.307 20.506 25.659 353 CB ILE 45 −9.272 21.591 25.542 354 CG2 ILE 45−8.707 21.594 24.110 355 CG1 ILE 45 −9.900 22.923 25.974 356 CD1 ILE 45−9.461 24.129 25.140 357 C ILE 45 −9.652 19.167 25.549 358 O ILE 45−10.257 18.225 25.044 359 N VAL 46 −8.401 19.041 26.031 360 CA VAL 46−7.607 17.911 25.638 361 CB VAL 46 −6.242 18.309 25.163 362 CG1 VAL 46−5.742 17.277 24.133 363 CG2 VAL 46 −6.370 19.732 24.586 364 C VAL 46−7.433 16.982 26.792 365 O VAL 46 −8.174 17.037 27.774 366 N GLY 47−6.443 16.073 26.678 367 CA GLY 47 −6.266 15.067 27.678 368 C GLY 47−5.201 14.137 27.197 369 O GLY 47 −5.414 12.932 27.052 370 N TYR 48−3.995 14.680 26.964 371 CA TYR 48 −2.928 13.780 26.685 372 CB TYR 48−1.611 14.479 26.283 373 CG TYR 48 −0.700 13.375 25.888 374 CD1 TYR 480.166 12.828 26.803 375 CD2 TYR 48 −0.737 12.887 24.604 376 CE1 TYR 480.997 11.794 26.429 377 CE2 TYR 48 0.086 11.857 24.219 378 CZ TYR 480.949 11.315 25.140 379 OH TYR 48 1.794 10.254 24.743 380 C TYR 48−2.736 12.988 27.931 381 O TYR 48 −2.443 13.535 28.991 382 N VAL 49−2.943 11.672 27.806 383 CA VAL 49 −2.937 10.710 28.867 384 CB VAL 49−3.953 9.670 28.471 385 CG1 VAL 49 −3.787 8.377 29.262 386 CG2 VAL 49−5.353 10.285 28.586 387 C VAL 49 −1.543 10.127 28.935 388 O VAL 49−1.029 9.637 27.929 389 N ILE 50 −0.863 10.182 30.110 390 CA ILE 500.464 9.610 30.109 391 CB ILE 50 1.513 10.306 30.962 392 CG2 ILE 501.584 9.635 32.349 393 CG1 ILE 50 2.859 10.346 30.197 394 CD1 ILE 504.045 10.807 31.038 395 C ILE 50 0.340 8.207 30.603 396 O ILE 50 −0.5397.910 31.413 397 N GLY 51 1.218 7.311 30.112 398 CA GLY 51 1.168 5.91630.442 399 C GLY 51 0.972 5.179 29.156 400 O GLY 51 1.575 5.494 28.120401 N THR 52 0.071 4.174 29.216 402 CA THR 52 −0.630 3.861 28.018 403 CBTHR 52 −1.885 3.097 28.226 404 OG1 THR 52 −2.903 3.631 27.382 405 CG2THR 52 −2.302 3.209 29.699 406 C THR 52 −1.026 5.184 27.504 407 O THR 52−1.652 5.982 28.195 408 N GLN 53 −0.543 5.487 26.299 409 CA GLN 53−0.666 6.826 25.861 410 CB GLN 53 0.465 7.278 24.938 411 CG GLN 53 1.8297.230 25.619 412 CD GLN 53 2.877 7.428 24.527 413 OE1 GLN 53 4.071 7.42324.817 414 NE2 GLN 53 2.415 7.631 23.269 415 C GLN 53 −1.911 6.90125.071 416 O GLN 53 −2.675 5.939 24.953 417 N GLN 54 −2.126 8.099 24.524418 CA GLN 54 −3.322 8.381 23.827 419 CB GLN 54 −4.581 7.869 24.548 420CG GLN 54 −5.803 7.545 23.681 421 CD GLN 54 −6.763 6.795 24.602 422 OE1GLN 54 −7.869 6.440 24.191 423 NE2 GLN 54 −6.317 6.525 25.855 424 C GLN54 −3.385 9.847 23.867 425 O GLN 54 −2.383 10.544 24.018 426 N ALA 55−4.611 10.320 23.732 427 CA ALA 55 −4.964 11.678 23.836 428 CB ALA 55−4.299 12.589 22.795 429 C ALA 55 −6.381 11.547 23.491 430 O ALA 55−6.808 10.517 22.966 431 N THR 56 −7.166 12.548 23.867 432 CA THR 56−8.525 12.196 24.021 433 CB THR 56 −8.680 11.127 25.065 434 OG1 THR 56−10.048 10.868 25.330 435 CG2 THR 56 −7.949 11.563 26.341 436 C THR 56−9.129 13.438 24.512 437 O THR 56 −8.433 14.257 25.105 438 N PRO 57−10.386 13.617 24.283 439 CA PRO 57 −10.840 14.948 24.446 440 CD PRO 57−10.906 13.108 23.022 441 CB PRO 57 −10.753 15.558 23.064 442 CG PRO 57−10.925 14.353 22.102 443 C PRO 57 −12.277 14.754 24.709 444 O PRO 57−12.690 13.664 25.104 445 N GLY 58 −13.044 15.789 24.354 446 CA GLY 58−14.417 15.618 24.081 447 C GLY 58 −14.982 16.963 23.754 448 O GLY 58−15.127 17.365 22.609 449 N PRO 59 −15.355 17.610 24.822 450 CA PRO 59−16.534 18.438 24.829 451 CD PRO 59 −14.982 17.108 26.133 452 CB PRO 59−16.902 18.641 26.295 453 CG PRO 59 −15.972 17.701 27.113 454 C PRO 59−16.384 19.730 24.072 455 O PRO 59 −17.351 20.488 23.955 456 N ALA 60−15.174 20.053 23.589 457 CA ALA 60 −14.948 21.440 23.352 458 CB ALA 60−13.956 22.042 24.364 459 C ALA 60 −14.376 21.600 21.978 460 O ALA 60−14.208 20.628 21.243 461 N TYR 61 −14.084 22.858 21.589 462 CA TYR 61−13.610 23.128 20.271 463 CB TYR 61 −13.226 24.602 20.021 464 CG TYR 61−14.081 25.271 18.987 465 CD1 TYR 61 −15.326 24.792 18.644 466 CD2 TYR61 −13.633 26.405 18.341 467 CE1 TYR 61 −16.091 25.442 17.697 468 CE2TYR 61 −14.398 27.051 17.398 469 CZ TYR 61 −15.641 26.576 17.060 470 OHTYR 61 −16.420 27.244 16.084 471 C TYR 61 −12.374 22.322 20.061 472 OTYR 61 −11.466 22.302 20.890 473 N SER 62 −12.322 21.656 18.897 474 CASER 62 −11.132 21.011 18.452 475 CB SER 62 −11.338 19.535 18.129 476 OGSER 62 −10.962 18.728 19.229 477 C SER 62 −10.819 21.616 17.147 478 OSER 62 −10.097 20.995 16.364 479 N GLY 63 −11.403 22.814 16.910 480 CAGLY 63 −11.507 23.438 15.618 481 C GLY 63 −10.201 23.285 14.938 482 OGLY 63 −10.113 22.656 13.879 483 N ARG 64 −9.146 23.793 15.599 484 CAARG 64 −7.828 23.351 15.288 485 CB ARG 64 −7.197 24.077 14.086 486 CGARG 64 −7.962 25.330 13.656 487 CD ARG 64 −8.229 26.327 14.787 488 NEARG 64 −9.590 26.901 14.538 489 CZ ARG 64 −10.205 27.660 15.488 490 NH1ARG 64 −9.543 27.976 16.636 561 CD1 LEU 73 −4.101 21.905 24.208 562 CLEU 73 −0.644 23.882 21.888 563 O LEU 73 −0.703 25.100 22.054 564 N LEU74 −0.541 23.324 20.666 565 CA LEU 74 −0.577 24.150 19.501 566 CB LEU 74−0.274 23.375 18.201 567 CG LEU 74 −0.808 24.042 16.911 568 CD2 LED 74−0.666 23.133 15.669 569 CD1 LEU 74 −0.158 25.407 16.695 570 C LEU 74−1.972 24.633 19.399 571 O LEU 74 −2.902 23.926 19.782 572 N ILE 75−2.157 25.860 18.887 573 CA ILE 75 −3.512 26.245 18.647 574 CB ILE 75−4.128 27.128 19.700 575 CG2 ILE 75 −3.089 28.175 20.123 576 CG1 ILE 75−5.456 27.716 19.186 577 CD1 ILE 75 −6.173 28.587 20.215 578 C ILE 75−3.577 26.941 17.331 579 O ILE 75 −2.924 27.961 17.098 580 N GLN 76−4.373 26.349 16.421 581 CA GLN 76 −4.446 26.798 15.067 582 CB GLN 76−4.687 25.657 14.062 583 CG GLN 76 −3.914 24.388 14.388 584 CD GLN 76−4.044 23.483 13.175 585 OE1 GLN 76 −5.039 23.541 12.453 586 NE2 GLN 76−3.011 22.634 12.947 587 C GLN 76 −5.615 27.706 14.935 588 O GLN 76−6.298 27.983 15.924 589 N ASN 77 −5.828 28.166 13.676 590 CA ASN 77−6.488 29.387 13.266 591 CB ASN 77 −7.436 29.203 12.072 592 CG ASN 77−6.569 28.673 10.938 593 OD1 ASN 77 −7.054 28.007 10.025 594 ND2 ASN 77−5.237 28.957 11.000 595 C ASN 77 −7.196 30.045 14.405 596 O ASN 77−8.422 30.116 14.467 597 N VAL 78 −6.384 30.540 15.358 598 CA VAL 78−6.874 31.028 16.616 599 CB VAL 78 −5.750 31.510 17.501 600 CG1 VAL 78−4.730 32.260 16.638 601 CG2 VAL 78 −6.329 32.341 18.654 602 C VAL 78−7.795 32.175 16.361 603 O VAL 78 −8.952 32.152 16.776 604 N THR 79−7.280 33.207 15.664 605 CA THR 79 −7.887 34.508 15.528 606 CB THR 79−9.109 34.605 14.652 607 OG1 THR 79 −10.140 33.768 15.153 608 CG2 THR 79−8.754 34.237 13.202 609 C THR 79 −8.299 35.077 16.839 610 O THR 79−8.045 34.518 17.903 611 N GLN 80 −8.927 36.263 16.743 612 CA GLN 80−9.278 37.115 17.839 613 CB GLN 80 −9.966 38.416 17.379 614 CG GLN 80−11.104 38.832 18.311 615 CD GLN 80 −11.897 39.956 17.666 616 OE1 GLN 80−12.979 40.259 18.160 617 NE2 GLN 80 −11.368 40.589 16.585 618 C GLN 80−10.252 36.411 18.719 619 O GLN 80 −10.239 36.617 19.933 620 N ASN 81−11.127 35.583 18.117 621 CA ASN 81 −12.180 34.965 18.867 622 CB ASN 81−13.014 33.953 18.057 623 CG ASN 81 −14.278 34.636 17.541 624 OD1 ASN 81−15.236 33.957 17.174 625 ND2 ASN 81 −14.303 35.999 17.501 626 C ASN 81−11.585 34.257 20.048 627 O ASN 81 −12.128 34.343 21.145 628 N ASP 82−10.439 33.567 19.879 629 CA ASP 82 −9.926 32.752 20.948 630 CB ASP 82−9.210 31.462 20.480 491 NH2 ARG 64 −11.487 28.092 15.294 492 C ARG 64−6.987 23.600 16.495 493 O ARG 64 −6.627 24.732 16.803 494 N GLU 65−6.657 22.513 17.214 495 CA GLU 65 −5.674 22.584 18.246 496 CB GLU 65−6.211 23.128 19.585 497 CG GLU 65 −6.537 24.624 19.586 498 CD GLU 65−8.040 24.778 19.615 499 OE1 GLU 65 −8.753 23.746 19.495 500 OE2 GLU 65−8.484 25.946 19.766 501 C GLU 65 −5.217 21.176 18.451 502 O GLU 65−5.930 20.239 18.103 503 N THR 66 −3.990 21.000 18.983 504 CA THR 66−3.457 19.696 19.247 505 CB THR 66 −2.594 19.179 18.129 506 OG1 THR 66−3.337 19.179 16.925 507 CG2 THR 66 −2.134 17.738 18.442 508 C THR 66−2.592 19.837 20.464 509 O THR 66 −2.309 20.942 20.917 510 N ILE 67−2.162 18.715 21.066 511 CA ILE 67 −1.377 18.852 22.260 512 CB ILE 67−2.030 18.256 23.485 513 CG2 ILE 67 −1.762 16.741 23.470 514 CG1 ILE 67−1.523 18.973 24.744 515 CD1 ILE 67 −1.647 18.108 25.988 516 C ILE 67−0.085 18.121 22.033 517 O ILE 67 0.077 17.372 21.068 518 N TYR 68 0.89518.353 22.922 519 CA TYR 68 2.175 17.733 22.802 520 CB TYR 68 3.30518.759 22.632 521 CG TYR 68 3.391 18.963 21.166 522 CD1 TYR 68 4.36518.322 20.436 523 CD2 TYR 68 2.488 19.780 20.528 524 CE1 TYR 68 4.44318.502 19.074 525 CE2 TYR 68 2.555 19.970 19.174 526 CZ TYR 68 3.53619.332 18.451 527 OH TYR 68 3.610 19.528 17.056 528 C TYR 68 2.44316.989 24.073 529 O TYR 68 2.042 17.428 25.146 530 N PRO 69 3.119 15.87723.982 531 CA PRO 69 3.371 15.070 25.143 532 CD PRO 69 3.125 15.10522.753 533 CB PRO 69 4.107 13.843 24.610 534 CG PRO 69 3.625 13.69623.148 535 C PRO 69 4.137 15.824 26.193 536 O PRO 69 4.095 15.430 27.358537 N ASN 70 4.859 16.896 25.815 538 CA ASN 70 5.639 17.604 26.791 539CB ASN 70 6.898 18.290 26.230 540 CG ASN 70 6.452 19.157 25.076 541 OD1ASN 70 6.234 18.678 23.961 542 ND2 ASN 70 6.301 20.479 25.348 543 C ASN70 4.768 18.682 27.345 544 O ASN 70 5.198 19.472 28.186 545 N ALA 713.504 18.717 26.889 546 CA ALA 71 2.503 19.609 27.386 547 CB ALA 712.499 19.725 28.914 548 C ALA 71 2.696 20.958 26.773 549 O ALA 71 2.68121.983 27.459 550 N SER 72 2.834 20.976 25.433 551 CA SER 72 2.62022.159 24.653 552 CB SER 72 3.553 22.293 23.432 553 OG SER 72 4.67823.098 23.731 554 C SER 72 1.262 22.000 24.063 555 O SER 72 0.858 20.87023.809 556 N LEU 73 0.524 23.105 23.803 557 CA LEU 73 −0.688 22.94123.047 558 CB LEU 73 −1.986 23.243 23.817 559 CG LEU 73 −3.230 22.61323.158 560 CD2 LEU 73 −4.021 23.616 22.299 631 CG ASP 82 −10.228 30.41120.064 632 OD1 ASP 82 −10.590 29.546 20.908 633 OD2 ASP 82 −10.64630.443 18.880 634 C ASP 82 −8.947 33.511 21.791 635 O ASP 82 −8.31432.915 22.663 636 N THR 83 −8.786 34.828 21.561 637 CA THR 83 −7.83235.573 22.332 638 CB THR 83 −7.829 37.042 22.008 639 OG1 THR 83 −6.51037.570 22.024 640 CG2 THR 83 −8.706 37.776 23.037 641 C THR 83 −8.20435.398 23.769 642 O THR 83 −9.339 35.038 24.069 643 N GLY 84 −7.25735.608 24.707 644 CA GLY 84 −7.626 35.517 26.094 645 C GLY 84 −6.83934.440 26.784 646 O GLY 84 −5.699 34.137 26.433 647 N PHE 85 −7.46333.862 27.832 648 CA PHE 85 −6.825 32.993 28.788 649 CB PHE 85 −7.60132.867 30.124 650 CG PHE 85 −6.648 32.469 31.200 651 CD1 PHE 85 −5.34832.913 31.193 652 CD2 PHE 85 −7.070 31.682 32.257 653 CE1 PHE 85 −4.47132.532 32.196 654 CE2 PHE 85 −6.198 31.295 33.255 655 CZ PHE 85 −4.88931.700 33.203 656 C PHE 85 −6.779 31.609 28.260 657 O PHE 85 −7.60731.204 27.445 658 N TYR 86 −5.817 30.830 28.784 659 CA TYR 86 −5.92629.397 28.775 660 CB TYR 86 −5.314 28.681 27.558 661 CG TYR 86 −6.15129.054 26.385 662 CD1 TYR 86 −5.794 30.119 25.587 663 CD2 TYR 86 −7.29928.351 26.090 664 CE1 TYR 86 −6.572 30.471 24.505 665 CE2 TYR 86 −8.08328.687 25.011 666 CZ TYR 86 −7.712 29.754 24.220 667 OH TYR 86 −8.51830.107 23.115 668 C TYR 86 −5.176 28.918 29.958 669 O TYR 86 −4.21929.551 30.408 670 N THR 87 −5.604 27.780 30.514 671 CA THR 87 −4.89427.338 31.666 672 CB THR 87 −5.697 27.360 32.923 673 OG1 THR 87 −4.84527.293 34.059 674 CG2 THR 87 −6.616 26.124 32.911 675 C THR 87 −4.59925.912 31.445 676 O THR 87 −4.955 25.334 30.419 677 N LEU 88 −3.93625.304 32.430 678 CA LEU 88 −3.729 23.915 32.232 679 CB LEU 88 −2.27423.588 31.867 680 CG LEU 88 −1.978 22.081 31.671 681 CD2 LEU 88 −0.67521.673 32.376 682 CD1 LEU 88 −2.030 21.700 30.187 683 C LEU 88 −4.07623.255 33.520 684 O LEU 88 −3.803 23.799 34.588 685 N GLN 89 −4.71422.068 33.448 686 CA GLN 89 −4.878 21.330 34.660 687 CB GLN 89 −6.32721.095 35.073 688 CG GLN 89 −6.421 20.539 36.492 689 CD GLN 89 −7.81819.973 36.711 690 OE1 GLN 89 −8.001 19.014 37.458 691 NE2 GLN 89 −8.81520.562 36.010 692 C GLN 89 −4.224 19.994 34.486 693 O GLN 89 −4.19819.444 33.393 694 N VAL 90 −3.672 19.423 35.571 695 CA VAL 90 −3.01518.162 35.446 696 CB VAL 90 −1.564 18.296 35.068 697 CG1 VAL 90 −0.85316.928 35.162 698 CG2 VAL 90 −1.469 19.047 33.713 699 C VAL 90 −3.06517.520 36.814 700 O VAL 90 −3.102 18.197 37.847 701 N ILE 91 −3.10016.169 36.789 702 CA ILE 91 −3.311 15.302 37.917 703 CB ILE 91 −4.47714.360 37.757 704 CG2 ILE 91 −4.628 13.584 39.088 705 CG1 ILE 91 −5.73715.076 37.252 706 CD1 ILE 91 −5.676 15.563 35.796 707 C ILE 91 −2.19214.326 37.890 708 O ILE 91 −1.954 13.676 36.875 709 N LYS 92 −1.53714.106 39.030 710 CA LYS 92 −1.028 12.778 39.161 711 CB LYS 92 0.49212.723 39.353 712 CG LYS 92 1.060 14.143 39.448 713 CD LYS 92 2.54914.263 39.113 714 CE LYS 92 2.955 15.635 38.568 715 NZ LYS 92 3.72116.387 39.588 716 C LYS 92 −1.717 12.275 40.373 717 O LYS 92 −2.11713.085 41.204 718 N SER 93 −1.937 10.952 40.455 719 CA SER 93 −2.68210.423 41.553 720 CB SER 93 −2.939 8.923 41.388 721 OG SER 93 −4.1948.585 41.954 722 C SER 93 −1.855 10.631 42.783 723 O SER 93 −1.040 9.77843.133 724 N ASP 94 −2.030 11.799 43.449 725 CA ASP 94 −1.146 12.18244.512 726 CB ASP 94 0.333 11.852 44.251 727 CG ASP 94 0.725 11.07645.493 728 OD1 ASP 94 1.441 10.046 45.379 729 OD2 ASP 94 0.290 11.52846.585 730 C ASP 94 −1.238 13.660 44.803 731 O ASP 94 −1.208 14.06145.966 732 N LEU 95 −1.346 14.522 43.770 733 CA LEU 95 −1.591 15.91044.067 734 CB LEU 95 −0.337 16.711 44.489 735 CG LEU 95 −0.514 17.72545.662 736 CD2 LEU 95 −1.107 17.051 46.915 737 CD1 LEU 95 −1.271 19.00545.253 738 C LEU 95 −2.141 16.537 42.819 739 O LEU 95 −1.685 16.25141.712 740 N VAL 96 −3.164 17.400 42.957 741 CA VAL 96 −3.701 18.03341.792 742 CB VAL 96 −5.142 18.430 41.903 743 CG1 VAL 96 −6.019 17.28741.368 744 CG2 VAL 96 −5.442 18.849 43.350 745 C VAL 96 −2.944 19.29841.647 746 O VAL 96 −2.690 20.010 42.619 747 N ASN 97 −2.553 19.61340.404 748 CA ASN 97 −1.970 20.888 40.170 749 CB ASN 97 −0.626 20.82339.429 750 CG ASN 97 0.387 20.330 40.445 751 OD1 ASN 97 1.530 20.03840.096 752 ND2 ASN 97 −0.032 20.264 41.734 753 C ASN 97 −2.911 21.58939.264 754 O ASN 97 −3.474 20.987 38.349 755 N GLU 98 −3.088 22.89939.480 756 CA GLU 98 −3.452 23.691 38.355 757 CB GLU 98 −4.463 24.81438.648 758 CG GLU 98 −4.922 25.574 37.394 759 CD GLU 98 −6.329 25.13437.023 760 OE1 GLU 98 −6.679 25.159 35.814 761 OE2 GLU 98 −7.081 24.79237.974 762 C GLU 98 −2.184 24.342 37.966 763 O GLU 98 −1.272 23.69937.455 764 N GLU 99 −2.119 25.656 38.250 765 CA GLU 99 −1.052 26.53437.901 766 CB GLU 99 0.117 26.601 38.885 767 CG GLU 99 1.033 27.73738.443 768 CD GLU 99 2.341 27.685 39.205 769 OE1 GLU 99 2.513 26.80740.100 770 OE2 GLU 99 3.206 28.536 38.879 771 C GLU 99 −0.472 26.20736.563 772 O GLU 99 0.360 25.314 36.405 773 N ALA 100 −0.872 27.01335.571 774 CA ALA 100 −0.391 26.940 34.232 775 CB ALA 100 −1.018 25.76533.466 776 C ALA 100 −0.883 28.203 33.611 777 O ALA 100 −1.966 28.23833.034 778 N THR 101 −0.131 29.302 33.789 779 CA THR 101 −0.644 30.60933.487 780 CB THR 101 −0.269 31.608 34.549 781 OG1 THR 101 −0.835 31.18135.771 782 CG2 THR 101 −0.787 33.021 34.212 783 C THR 101 −0.066 31.04232.179 784 O THR 101 0.885 30.442 31.684 785 N GLY 102 −0.633 32.09431.567 786 CA GLY 102 −0.106 32.574 30.329 787 C GLY 102 −1.270 33.10429.569 788 O GLY 102 −2.257 32.400 29.357 789 N GLN 103 −1.196 34.37829.148 790 CA GLN 103 −2.265 34.910 28.358 791 CB GLN 103 −2.925 36.13629.007 792 CG GLN 103 −4.130 36.705 28.255 793 CD GLN 103 −4.498 37.97828.991 794 OE1 GLN 103 −5.454 38.693 28.693 795 NE2 GLN 103 −3.67038.286 30.025 796 C GLN 103 −1.645 35.364 27.081 797 O GLN 103 −0.42935.507 26.986 798 N PHE 104 −2.475 35.591 26.044 799 CA PHE 104 −1.94336.202 24.868 800 CB PHE 104 −1.227 35.235 23.897 801 CG PHE 104 −2.16934.199 23.377 802 CD1 PHE 104 −2.906 33.418 24.234 803 CD2 PHE 104−2.303 33.978 22.018 804 CE1 PHE 104 −3.756 32.453 23.748 805 CE2 PHE104 −3.153 33.014 21.522 806 CZ PHE 104 −3.880 32.243 22.391 807 C PHE104 −3.086 36.849 24.164 808 O PHE 104 −4.245 36.536 24.421 809 N HIS105 −2.784 37.819 23.285 810 CA HIS 105 −3.829 38.578 22.669 811 ND1 HIS105 −4.810 40.669 24.965 812 CG HIS 105 −3.638 40.500 24.268 813 CB HIS105 −3.598 40.086 22.819 814 NE2 HIS 105 −3.163 41.097 26.388 815 CD2HIS 105 −2.632 40.759 25.149 816 CE1 HIS 105 −4.467 41.030 26.230 817 CHIS 105 −3.792 38.201 21.223 818 O HIS 105 −3.141 37.220 20.869 819 NVAL 106 −4.483 38.955 20.339 820 CA VAL 106 −4.363 38.711 18.923 821 CBVAL 106 −5.384 37.763 18.369 822 CG1 VAL 106 −6.757 38.200 18.899 823CG2 VAL 106 −5.333 37.796 16.833 824 C VAL 106 −4.614 40.002 18.227 825O VAL 106 −5.538 40.735 18.577 826 N TYR 107 −3.792 40.323 17.213 827 CATYR 107 −4.027 41.572 16.568 828 CB TYR 107 −2.845 42.548 16.743 829 CGTYR 107 −2.693 42.754 18.238 830 CD1 TYR 107 −1.732 42.077 18.964 831CD2 TYR 107 −3.519 43.617 18.936 832 CE1 TYR 107 −1.609 42.240 20.330833 CE2 TYR 107 −3.417 43.795 20.300 834 CZ TYR 107 −2.431 43.124 20.997835 OH TYR 107 −2.314 43.298 22.387 836 C TYR 107 −4.293 41.284 15.120837 O TYR 107 −3.654 40.457 14.482 838 N PRO 108 −5.294 41.999 14.648839 CA PRO 108 −5.737 42.053 13.279 840 CD PRO 108 −5.871 43.064 15.448841 CB PRO 108 −7.084 42.769 13.320 842 CG PRO 108 −7.139 43.501 14.687843 C PRO 108 −4.767 42.897 12.513 844 O PRO 108 −4.129 43.738 13.143845 N GLU 109 −4.634 42.718 11.176 846 CA GLU 109 −3.552 43.320 10.423847 CB GLU 109 −3.484 42.849 8.968 848 CG GLU 109 −3.494 41.318 8.836849 CD GLU 109 −4.938 40.835 8.829 850 OE1 GLU 109 −5.307 40.101 9.782851 OE2 GLU 109 −5.674 41.213 7.883 852 C GLU 109 −3.681 44.817 10.430853 O GLU 109 −4.432 45.373 11.227 854 N LEU 110 −2.943 45.539 9.545 855CA LEU 110 −3.026 46.976 9.640 856 CB LEU 110 −2.017 47.650 10.584 857CG LEU 110 −2.258 49.172 10.584 858 CD2 LEU 110 −0.948 49.963 10.470 859CD1 LEU 110 −3.165 49.610 11.741 860 C LEU 110 −2.842 47.671 8.317 861 OLEU 110 −1.738 47.865 7.809 862 N PRO 111 −3.964 48.094 7.808 863 CA PRO111 −4.109 48.785 6.547 864 CD PRO 111 −5.222 47.778 8.447 865 CB PRO111 −5.605 48.910 6.305 866 CG PRO 111 −6.300 48.099 7.412 867 C PRO 111−3.503 50.157 6.564 868 O PRO 111 −3.177 50.654 7.642 869 N LYS 112−3.384 50.786 5.373 870 CA LYS 112 −2.617 51.993 5.253 871 CB LYS 112−2.128 52.305 3.826 872 CG LYS 112 −1.220 53.533 3.800 873 CD LYS 112−0.453 53.724 2.490 874 CE LYS 112 0.607 54.832 2.569 875 NZ LYS 1121.852 54.289 3.159 876 C LYS 112 −3.413 53.186 5.678 877 O LYS 112−4.555 53.420 5.285 878 N PRO 113 −2.710 53.948 6.486 879 CA PRO 113−3.076 55.274 6.907 880 CD PRO 113 −1.677 53.346 7.311 881 CB PRO 113−2.118 55.628 8.055 882 CG PRO 113 −1.470 54.295 8.497 883 C PRO 113−2.967 56.287 5.795 884 O PRO 113 −2.127 56.120 4.910 885 N SER 114−3.794 57.356 5.867 886 CA SER 114 −3.606 58.551 5.088 887 CB SER 114−4.729 58.809 4.084 888 OG SER 114 −4.459 60.003 3.359 889 C SER 114−3.609 59.718 6.035 890 O SER 114 −4.181 59.640 7.118 891 N ILE 115−2.965 60.847 5.637 892 CA ILE 115 −3.046 62.057 6.426 893 CB ILE 115−1.740 62.557 6.990 894 CG2 ILE 115 −0.781 62.821 5.820 895 CG1 ILE 115−2.003 63.810 7.860 896 CD1 ILE 115 −0.746 64.588 8.247 897 C ILE 115−3.547 63.167 5.542 898 O ILE 115 −3.208 63.239 4.365 899 N SER 116−4.385 64.061 6.105 900 CA SER 116 −4.943 65.165 5.374 901 CB SER 116−6.467 65.313 5.590 902 OG SER 116 −6.923 66.591 5.162 903 C SER 116−4.323 66.398 5.940 904 O SER 116 −4.683 66.824 7.036 905 N SER 117−3.361 67.005 5.220 906 CA SER 117 −2.806 68.240 5.684 907 CB SER 117−1.343 68.475 5.262 908 OG SER 117 −1.020 69.849 5.405 909 C SER 117−3.605 69.360 5.093 910 O SER 117 −4.176 69.244 4.010 911 N ASN 118−3.659 70.500 5.798 912 CA ASN 118 −4.327 71.621 5.208 913 CB ASN 118−5.505 72.143 6.067 914 CG ASN 118 −6.452 72.971 5.207 915 OD1 ASN 118−7.076 73.914 5.687 916 ND2 ASN 118 −6.555 72.607 3.901 917 C ASN 118−3.317 72.717 5.048 918 O ASN 118 −2.881 73.322 6.025 919 N ASN 119−2.922 73.007 3.787 920 CA ASN 119 −2.168 74.181 3.448 921 CB ASN 119−2.617 75.431 4.242 922 CG ASN 119 −2.050 76.687 3.586 923 OD1 ASN 119−1.279 76.605 2.633 924 ND2 ASN 119 −2.386 77.887 4.137 925 C ASN 119−0.697 73.935 3.642 926 O ASN 119 −0.259 73.489 4.701 927 N SER 1200.102 74.219 2.589 928 CA SER 120 1.509 73.927 2.599 929 CB SER 1201.944 73.138 1.355 930 OG SER 120 3.021 72.282 1.695 931 C SER 120 2.26875.228 2.605 932 O SER 120 3.168 75.440 3.421 933 N ASN 121 1.862 76.1771.721 934 CA ASN 121 2.153 77.586 1.908 935 CB ASN 121 1.288 78.5120.994 936 CG ASN 121 1.952 78.943 −0.311 937 OD1 ASN 121 2.097 80.143−0.566 938 ND2 ASN 121 2.328 77.953 −1.166 939 C ASN 121 1.765 77.9143.317 940 O ASN 121 0.984 77.194 3.929 941 N PRO 122 2.269 78.991 3.869942 CA PRO 122 2.093 79.357 5.261 943 CD PRO 122 3.013 79.951 3.084 944CB PRO 122 2.663 80.777 5.394 945 CG PRO 122 3.390 81.084 4.051 946 CPRO 122 0.617 79.283 5.633 947 O PRO 122 −0.201 79.294 4.718 948 N VAL123 0.208 79.184 6.918 949 CA VAL 123 0.887 78.882 8.152 950 CB VAL 1230.983 77.425 8.414 951 CG1 VAL 123 −0.470 76.943 8.541 952 CG2 VAL 1231.822 76.733 7.326 953 C VAL 123 2.237 79.484 8.259 954 O VAL 123 3.26378.811 8.297 955 N GLU 124 2.261 80.816 8.367 956 CA GLU 124 3.54281.388 8.517 957 CB GLU 124 3.554 82.885 8.384 958 CG GLU 124 2.41183.457 7.629 959 CD GLU 124 2.766 84.920 7.710 960 OE1 GLU 124 2.84885.552 6.621 961 OE2 GLU 124 2.934 85.414 8.857 962 C GLU 124 3.97481.159 9.918 963 O GLU 124 3.325 80.457 10.682 964 N ASP 125 5.08881.807 10.295 965 CA ASP 125 5.504 81.809 11.658 966 CB ASP 125 6.68382.746 11.906 967 CG ASP 125 7.888 81.999 11.366 968 OD1 ASP 125 9.02482.531 11.470 969 OD2 ASP 125 7.697 80.880 10.817 970 C ASP 125 4.35082.254 12.481 971 O ASP 125 3.895 83.397 12.375 972 N LYS 126 3.85281.301 13.296 973 CA LYS 126 2.922 81.503 14.373 974 CB LYS 126 2.77382.968 14.820 975 CG LYS 126 2.850 83.237 16.328 976 CD LYS 126 2.70584.724 16.637 977 CE LYS 126 1.317 85.119 17.133 978 NZ LYS 126 1.37385.461 18.569 979 C LYS 126 1.547 81.016 14.018 980 O LYS 126 0.66281.080 14.871 981 N ASP 127 1.324 80.492 12.789 982 CA ASP 127 0.04179.903 12.493 983 CB ASP 127 −0.330 79.870 11.002 984 CG ASP 127 −0.56581.307 10.576 985 OD1 ASP 127 −0.714 82.184 11.469 986 OD2 ASP 127−0.605 81.554 9.343 987 C ASP 127 0.030 78.481 12.944 988 O ASP 1270.760 78.098 13.855 989 N ALA 128 −0.854 77.649 12.352 990 CA ALA 128−1.000 76.356 12.958 991 CB ALA 128 −2.140 76.239 13.990 992 C ALA 128−1.263 75.313 11.938 993 O ALA 128 −2.273 75.327 11.237 994 N VAL 129−0.358 74.328 11.878 995 CA VAL 129 −0.658 73.150 11.142 996 CB VAL 1290.522 72.239 10.974 997 CG1 VAL 129 0.649 71.860 9.493 998 CG2 VAL 1291.761 72.926 11.575 999 C VAL 129 −1.636 72.431 11.994 1000 O VAL 129−1.804 72.757 13.173 1001 N ALA 130 −2.302 71.433 11.391 1002 CA ALA 130−2.990 70.405 12.094 1003 CB ALA 130 −4.485 70.689 12.347 1004 C ALA 130−2.898 69.245 11.167 1005 O ALA 130 −3.724 69.072 10.272 1006 N PHE 131−1.844 68.431 11.323 1007 CA PHE 131 −1.755 67.307 10.450 1008 CB PHE131 −0.338 66.707 10.342 1009 CG PHE 131 0.532 67.647 9.562 1010 CD1 PHE131 0.316 67.849 8.220 1011 CD2 PHE 131 1.582 68.323 10.154 1012 CE1 PHE131 1.100 68.710 7.486 1013 CE2 PHE 131 2.372 69.187 9.422 1014 CZ PHE131 2.134 69.389 8.088 1015 C PHE 131 −2.614 66.263 11.069 1016 O PHE131 −2.285 65.744 12.135 1017 N THR 132 −3.752 65.933 10.423 1018 CA THR132 −4.578 64.885 10.954 1019 CB THR 132 −6.035 65.211 11.047 1020 OG1THR 132 −6.408 65.332 12.421 1021 CG2 THR 132 −6.835 64.084 10.359 1022C THR 132 −4.464 63.679 10.078 1023 O THR 132 −4.552 63.759 8.851 1024 NCYS 133 −4.263 62.512 10.725 1025 CA CYS 133 −4.143 61.229 10.107 1026CB CYS 133 −3.330 60.260 10.989 1027 SG CYS 133 −2.968 58.665 10.2021028 C CYS 133 −5.533 60.709 10.008 1029 O CYS 133 −6.451 61.331 10.5461030 N GLU 134 −5.719 59.568 9.306 1031 CA GLU 134 −6.979 58.864 9.3051032 CB GLU 134 −8.006 59.303 8.241 1033 CG GLU 134 −8.386 60.783 8.2231034 CD GLU 134 −8.875 61.056 6.792 1035 OE1 GLU 134 −10.089 61.3506.626 1036 OE2 GLU 134 −8.050 60.952 5.845 1037 C GLU 134 −6.741 57.4248.974 1038 O GLU 134 −6.151 57.079 7.954 1039 N PRO 135 −7.243 56.5779.818 1040 CA PRO 135 −7.050 55.169 9.635 1041 CD PRO 135 −7.077 56.94011.202 1042 CB PRO 135 −6.083 54.735 10.725 1043 CG PRO 135 −6.05355.911 11.730 1044 C PRO 135 −8.395 54.592 9.934 1045 O PRO 135 −9.25655.315 10.433 1046 N GLU 136 −8.647 53.302 9.670 1047 CA GLU 136 −10.01152.974 9.955 1048 CB GLU 136 −10.824 52.670 8.682 1049 CG GLU 136−12.222 53.311 8.629 1050 CD GLU 136 −12.430 54.199 7.391 1051 OE1 GLU136 −13.086 55.255 7.599 1052 OE2 GLU 136 −11.970 53.877 6.258 1053 CGLU 136 −10.078 51.795 10.881 1054 O GLU 136 −11.143 51.205 11.063 1055N VAL 137 −8.939 51.440 11.516 1056 CA VAL 137 −8.882 50.306 12.398 1057CB VAL 137 −7.510 49.742 12.578 1058 CG1 VAL 137 −7.595 48.226 12.4231059 CG2 VAL 137 −6.554 50.414 11.587 1060 C VAL 137 −9.304 50.70013.786 1061 O VAL 137 −10.095 51.626 13.964 1062 N GLN 138 −8.764 49.97314.796 1063 CA GLN 138 −8.842 50.299 16.194 1064 CB GLN 138 −10.24050.058 16.814 1065 CG GLN 138 −10.721 48.607 16.952 1066 CD GLN 138−11.955 48.620 17.869 1067 OE1 GLN 138 −11.907 49.164 18.972 1068 NE2GLN 138 −13.072 47.996 17.415 1069 C GLN 138 −7.798 49.443 16.858 1070 OGLN 138 −7.244 48.548 16.226 1071 N ASN 139 −7.485 49.707 18.138 1072 CAASN 139 −6.303 49.207 18.783 1073 CB ASN 139 −6.298 47.704 19.084 1074CG ASN 139 −5.415 47.532 20.309 1075 OD1 ASN 139 −4.843 46.476 20.5691076 ND2 ASN 139 −5.278 48.644 21.080 1077 C ASN 139 −5.104 49.56217.969 1078 O ASN 139 −4.132 48.818 17.866 1079 N THR 140 −5.155 50.76817.399 1080 CA THR 140 −4.043 51.458 16.851 1081 CB THR 140 −4.50752.744 16.260 1082 OG1 THR 140 −4.937 53.616 17.288 1083 CG2 THR 140−5.678 52.413 15.318 1084 C THR 140 −3.169 51.790 18.009 1085 O THR 140−3.663 51.963 19.125 1086 N THR 141 −1.849 51.912 17.771 1087 CA THR 141−1.121 52.860 18.561 1088 CB THR 141 −0.353 52.325 19.721 1089 OG1 THR141 0.766 53.172 19.936 1090 CG2 THR 141 0.101 50.886 19.457 1091 C THR141 −0.172 53.570 17.665 1092 O THR 141 0.503 52.974 16.824 1093 N TYR142 −0.185 54.904 17.800 1094 CA TYR 142 0.042 55.732 16.664 1095 CB TYR142 −1.148 56.671 16.449 1096 CG TYR 142 −0.782 57.653 15.415 1097 CD1TYR 142 −0.547 57.247 14.118 1098 CD2 TYR 142 −0.709 58.981 15.731 1099CE1 TYR 142 −0.201 58.157 13.157 1100 CE2 TYR 142 −0.358 59.912 14.7931101 CZ TYR 142 −0.116 59.500 13.492 1102 OH TYR 142 0.231 60.430 12.5151103 C TYR 142 1.240 56.556 16.989 1104 O TYR 142 1.324 57.154 18.0411105 N LEU 143 2.213 56.613 16.039 1106 CA LEU 143 3.312 57.492 16.2751107 CB LEU 143 4.671 56.781 16.267 1108 CG LEU 143 5.088 56.308 17.6671109 CD2 LEU 143 5.573 54.858 17.666 1110 CD1 LEU 143 3.963 56.52518.691 1111 C LEU 143 3.307 58.512 15.196 1112 O LEU 143 2.573 58.39114.220 1113 N TRP 144 4.114 59.578 15.372 1114 CA TRP 144 4.133 60.68814.450 1115 CB TRP 144 3.713 62.007 15.134 1116 CG TRP 144 2.240 62.35015.026 1117 CD2 TRP 144 1.656 62.776 13.795 1118 CD1 TRP 144 1.24062.377 15.962 1119 NE1 TRP 144 0.067 62.808 15.384 1120 CE2 TRP 1440.313 63.059 14.048 1121 CE3 TRP 144 2.196 62.931 12.560 1122 CZ2 TRP144 −0.508 63.517 13.057 1123 CZ3 TRP 144 1.367 63.363 11.553 1124 CH2TRP 144 0.043 63.661 11.805 1125 C TRP 144 5.566 60.858 14.032 1126 OTRP 144 6.467 60.605 14.826 1127 N TRP 145 5.845 61.296 12.782 1128 CATRP 145 7.239 61.463 12.478 1129 CB TRP 145 7.893 60.229 11.809 1130 CGTRP 145 7.529 58.833 12.308 1131 CD2 TRP 145 7.836 58.261 13.601 1132CD1 TRP 145 6.890 57.852 11.615 1133 NE1 TRP 145 6.781 56.713 12.3721134 CE2 TRP 145 7.351 56.950 13.600 1135 CE3 TRP 145 8.491 58.76514.690 1136 CZ2 TRP 145 7.512 56.138 14.685 1137 CZ3 TRP 145 8.61657.958 15.798 1138 CH2 TRP 145 8.131 56.667 15.801 1139 C TRP 145 7.43962.634 11.552 1140 O TRP 145 6.476 63.222 11.055 1141 N VAL 146 8.73062.998 11.328 1142 CA VAL 146 9.114 64.106 10.490 1143 CB VAL 146 9.32265.392 11.235 1144 CG1 VAL 146 10.076 66.363 10.309 1145 CG2 VAL 1467.974 65.935 11.740 1146 C VAL 146 10.455 63.828 9.852 1147 O VAL 14611.445 63.596 10.542 1148 N ASN 147 10.509 63.909 8.507 1149 CA ASN 14711.674 63.844 7.669 1150 CB ASN 147 12.911 64.556 8.238 1151 CG ASN 14712.816 66.012 7.803 1152 OD1 ASN 147 13.401 66.881 8.445 1153 ND2 ASN147 12.066 66.283 6.703 1154 C ASN 147 11.975 62.411 7.458 1155 O ASN147 12.855 62.055 6.667 1156 N GLY 148 11.223 61.563 8.176 1157 CA GLY148 11.510 60.173 8.214 1158 C GLY 148 12.196 59.885 9.503 1159 O GLY148 12.950 58.920 9.587 1160 N GLN 149 11.976 60.699 10.554 1161 CA GLN149 12.668 60.327 11.754 1162 CB GLN 149 14.192 60.470 11.634 1163 CGGLN 149 14.985 59.402 12.380 1164 CD GLN 149 16.432 59.866 12.385 1165OE1 GLN 149 16.753 61.047 12.487 1166 NE2 GLN 149 17.353 58.881 12.2761167 C GLN 149 12.277 61.243 12.858 1168 O GLN 149 12.325 62.457 12.6761169 N SER 150 11.924 60.611 14.020 1170 CA SER 150 11.450 60.998 15.3431171 CB SER 150 12.513 60.814 16.430 1172 OG SER 150 11.974 60.09217.531 1173 C SER 150 10.970 62.400 15.494 1174 O SER 150 11.430 63.31614.832 1175 N LEU 151 10.049 62.643 16.444 1176 CA LEU 151 9.866 64.00816.808 1177 CB LEU 151 8.639 64.786 16.308 1178 CG LEU 151 8.983 66.26716.057 1179 CD2 LEU 151 8.033 67.262 16.758 1180 CD1 LEU 151 9.04666.530 14.548 1181 C LEU 151 9.473 63.957 18.209 1182 O LEU 151 8.27063.967 18.436 1183 N PRO 152 10.461 64.026 19.082 1184 CA PRO 152 10.32965.029 20.099 1185 CD PRO 152 11.766 64.222 18.476 1186 CB PRO 15210.820 66.299 19.414 1187 CG PRO 152 11.946 65.747 18.503 1188 C PRO 1528.993 65.165 20.713 1189 O PRO 152 8.672 64.424 21.648 1190 N VAL 1538.176 66.084 20.162 1191 CA VAL 153 7.202 66.877 20.871 1192 CB VAL 1536.440 66.293 22.066 1193 CG1 VAL 153 5.636 67.415 22.764 1194 CG2 VAL153 5.554 65.110 21.685 1195 C VAL 153 7.922 68.008 21.493 1196 O VAL153 8.920 67.822 22.175 1197 N SER 154 7.420 69.226 21.331 1198 CA SER154 7.918 70.230 22.217 1199 CB SER 154 8.762 71.331 21.539 1200 OG SER154 9.740 70.794 20.664 1201 C SER 154 6.701 70.922 22.660 1202 O SER154 5.651 70.735 22.042 1203 N PRO 155 6.837 71.725 23.684 1204 CA PRO155 5.773 72.513 24.223 1205 CD PRO 155 7.967 71.629 24.585 1206 CB PRO155 6.498 73.538 25.103 1207 CG PRO 155 7.742 72.756 25.609 1208 C PRO155 4.825 73.059 23.184 1209 O PRO 155 3.628 72.778 23.254 1210 N ARG156 5.331 73.809 22.193 1211 CA ARG 156 4.513 74.440 21.188 1212 CB ARG156 5.307 75.070 20.040 1213 CG ARG 156 6.569 74.291 19.684 1214 CD ARG156 7.373 74.983 18.582 1215 NE ARG 156 8.077 73.951 17.767 1216 CZ ARG156 8.351 74.211 16.449 1217 NH1 ARG 156 7.891 75.370 15.894 1218 NH2ARG 156 9.083 73.341 15.694 1219 C ARG 156 3.499 73.496 20.591 1220 OARG 156 2.378 73.923 20.329 1221 N LEU 157 3.822 72.209 20.329 1222 CALEU 157 2.837 71.450 19.586 1223 CB LEU 157 3.330 70.169 18.889 1224 CGLEU 157 4.517 70.376 17.937 1225 CD2 LEU 157 4.532 69.325 16.810 1226CD1 LEU 157 5.827 70.419 18.745 1227 C LEU 157 1.700 71.029 20.455 1228O LEU 157 1.270 71.760 21.347 1229 N GLN 158 1.137 69.835 20.151 1230 CAGLN 158 −0.057 69.313 20.769 1231 CB GLN 158 −1.132 70.373 21.097 1232CG GLN 158 −2.416 69.790 21.719 1233 CD GLN 158 −3.570 70.776 21.5741234 OE1 GLN 158 −4.598 70.661 22.245 1235 NE2 GLN 158 −3.404 71.77420.664 1236 C GLN 158 −0.703 68.394 19.773 1237 O GLN 158 −0.786 68.71618.594 1238 N LEU 159 −1.178 67.217 20.212 1239 CA LEU 159 −1.999 66.39719.360 1240 CB LEU 159 −1.282 65.165 18.772 1241 CG LEU 159 −0.47964.381 19.835 1242 CD2 LEU 159 0.998 64.832 19.838 1243 CD1 LEU 159−0.664 62.856 19.694 1244 C LEU 159 −3.051 65.851 20.257 1245 O LEU 159−2.795 65.601 21.432 1246 N SER 160 −4.275 65.643 19.745 1247 CA SER 160−5.245 65.095 20.643 1248 CB SER 160 −6.448 66.028 20.932 1249 OG SER160 −6.995 66.511 19.716 1250 C SER 160 −5.764 63.845 20.015 1251 O SER160 −5.169 63.325 19.070 1252 N ASN 161 −6.900 63.350 20.549 1253 CA ASN161 −7.736 62.387 19.876 1254 CB ASN 161 −8.459 62.952 18.643 1255 CGASN 161 −9.907 63.251 18.970 1256 OD1 ASN 161 −10.682 63.529 18.057 1257ND2 ASN 161 −10.281 63.170 20.274 1258 C ASN 161 −6.917 61.264 19.3521259 O ASN 161 −6.654 61.208 18.148 1260 N GLY 162 −6.518 60.340 20.2451261 CA GLY 162 −5.761 59.170 19.909 1262 C GLY 162 −4.647 59.564 18.9871263 O GLY 162 −4.484 58.975 17.917 1264 N ASN 163 −3.850 60.584 19.3671265 CA ASN 163 −2.666 60.951 18.610 1266 CB ASN 163 −1.637 59.81818.422 1267 CG ASN 163 −0.793 59.594 19.660 1268 OD1 ASN 163 0.43259.648 19.584 1269 ND2 ASN 163 −1.469 59.369 20.806 1270 C ASN 163−3.036 61.250 17.195 1271 O ASN 163 −2.149 61.330 16.333 1272 N MET 164−4.316 61.360 16.858 1273 CA MET 164 −4.629 61.310 15.468 1274 CB MET164 −6.141 61.091 15.285 1275 CG MET 164 −6.783 61.665 14.029 1276 SDMET 164 −8.490 61.061 13.860 1277 CE MET 164 −8.741 61.717 12.193 1278 CMET 164 −4.214 62.627 14.927 1279 O MET 164 −3.118 62.800 14.398 1280 NTHR 165 −5.090 63.608 15.144 1281 CA THR 165 −4.793 65.006 15.106 1282CB THR 165 −5.780 65.760 15.932 1283 OG1 THR 165 −5.924 65.092 17.1711284 CG2 THR 165 −7.118 65.747 15.182 1285 C THR 165 −3.469 65.26115.737 1286 O THR 165 −3.056 64.604 16.693 1287 N LEU 166 −2.790 66.28315.209 1288 CA LEU 166 −1.711 66.913 15.895 1289 CB LEU 166 −0.35866.268 15.593 1290 CG LEU 166 0.811 67.248 15.674 1291 CD2 LEU 166 1.94066.720 14.779 1292 CD1 LEU 166 1.231 67.581 17.119 1293 C LEU 166 −1.67968.289 15.334 1294 O LEU 166 −1.769 68.477 14.121 1295 N THR 167 −1.62369.297 16.209 1296 CA THR 167 −1.789 70.641 15.770 1297 CB THR 167−2.934 71.320 16.455 1298 OG1 THR 167 −2.654 72.698 16.649 1299 CG2 THR167 −3.141 70.626 17.808 1300 C THR 167 −0.539 71.364 16.141 1301 O THR167 −0.164 71.418 17.311 1302 N LEU 168 0.154 71.941 15.140 1303 CA LEU168 1.332 72.688 15.454 1304 CB LEU 168 2.463 72.536 14.422 1305 CG LEU168 3.765 73.243 14.864 1306 CD2 LEU 168 4.876 73.109 13.804 1307 CD1LEU 168 4.170 72.800 16.281 1308 C LEU 168 0.944 74.126 15.445 1309 OLEU 168 0.661 74.688 14.391 1310 N LEU 169 0.927 74.767 16.632 1311 CALEU 169 0.801 76.194 16.719 1312 CB LEU 169 −0.654 76.676 16.804 1313 CGLEU 169 −0.784 78.168 17.167 1314 CD2 LEU 169 −1.919 78.398 18.176 1315CD1 LEU 169 −0.961 79.040 15.914 1316 C LEU 169 1.415 76.560 18.023 1317O LEU 169 1.122 75.927 19.033 1318 N SER 170 2.285 77.588 18.070 1319 CASER 170 2.758 78.307 16.922 1320 CB SER 170 3.559 79.563 17.319 1321 OGSER 170 4.427 79.952 16.261 1322 C SER 170 3.671 77.384 16.170 1323 OSER 170 4.326 76.518 16.751 1324 N VAL 171 3.725 77.527 14.834 1325 CAVAL 171 4.681 76.761 14.094 1326 CB VAL 171 4.106 76.252 12.797 1327 CG1VAL 171 3.430 77.432 12.071 1328 CG2 VAL 171 5.166 75.522 11.956 1329 CVAL 171 5.828 77.704 13.859 1330 O VAL 171 5.734 78.876 14.209 1331 NLYS 172 6.966 77.237 13.303 1332 CA LYS 172 8.013 78.196 13.041 1333 CBLYS 172 8.874 78.527 14.316 1334 CG LYS 172 10.371 78.134 14.439 1335 CDLYS 172 10.656 77.034 15.470 1336 CE LYS 172 12.140 76.833 15.838 1337NZ LYS 172 13.033 77.697 15.022 1338 C LYS 172 8.761 77.718 11.817 1339O LYS 172 8.163 77.078 10.956 1340 N ARG 173 10.066 78.040 11.671 1341CA ARG 173 10.813 77.730 10.488 1342 CB ARG 173 11.926 78.747 10.2301343 CG ARG 173 13.211 78.353 10.949 1344 CD ARG 173 14.439 79.11310.457 1345 NE ARG 173 15.286 79.419 11.639 1346 CZ ARG 173 15.68280.702 11.881 1347 NH1 ARG 173 15.273 81.695 11.024 1348 NH2 ARG 17316.469 81.003 12.946 1349 C ARG 173 11.500 76.412 10.690 1350 O ARG 17312.143 75.886 9.780 1351 N ASN 174 11.382 75.844 11.905 1352 CA ASN 17412.037 74.600 12.199 1353 CB ASN 174 11.897 74.172 13.680 1354 CG ASN174 12.938 73.107 14.057 1355 OD1 ASN 174 12.833 72.506 15.124 1356 ND2ASN 174 13.957 72.871 13.193 1357 C ASN 174 11.375 73.548 11.366 1358 OASN 174 11.972 72.522 11.046 1359 N ASP 175 10.099 73.775 11.011 1360 CAASP 175 9.255 72.719 10.537 1361 CB ASP 175 7.778 72.996 10.819 1362 CGASP 175 7.652 73.001 12.335 1363 OD1 ASP 175 7.430 74.093 12.917 1364OD2 ASP 175 7.800 71.907 12.944 1365 C ASP 175 9.412 72.498 9.064 1366 OASP 175 8.595 71.808 8.454 1367 N ALA 176 10.464 73.065 8.447 1368 CAALA 176 10.625 72.920 7.027 1369 CB ALA 176 11.740 73.814 6.436 1370 CALA 176 11.006 71.495 6.764 1371 O ALA 176 12.188 71.163 6.733 1372 NGLY 177 10.010 70.602 6.564 1373 CA GLY 177 10.337 69.217 6.356 1374 CGLY 177 9.115 68.476 5.895 1375 O GLY 177 8.077 69.067 5.594 1376 N SER178 9.213 67.132 5.813 1377 CA SER 178 8.078 66.354 5.392 1378 CB SER178 8.341 65.488 4.143 1379 OG SER 178 7.114 65.059 3.574 1380 C SER 1787.735 65.418 6.494 1381 O SER 178 8.597 64.710 6.993 1382 N TYR 1796.462 65.386 6.914 1383 CA TYR 179 6.140 64.650 8.094 1384 CB TYR 1795.278 65.474 9.077 1385 CG TYR 179 6.029 66.685 9.561 1386 CD1 TYR 1795.503 67.420 10.607 1387 CD2 TYR 179 7.227 67.092 9.011 1388 CE1 TYR 1796.148 68.536 11.085 1389 CE2 TYR 179 7.881 68.208 9.484 1390 CZ TYR 1797.343 68.930 10.520 1391 OH TYR 179 8.030 70.067 10.987 1392 C TYR 1795.356 63.447 7.668 1393 O TYR 179 4.378 63.560 6.930 1394 N GLU 1805.779 62.250 8.121 1395 CA GLU 180 5.070 61.062 7.768 1396 CB GLU 1805.970 59.821 7.632 1397 CG GLU 180 5.277 58.645 6.040 1398 CD GLU 1805.889 58.420 5.558 1399 OE1 GLU 180 7.122 58.176 5.480 1400 OE2 GLU 1805.132 58.487 4.556 1401 C GLU 180 4.074 60.804 8.848 1402 O GLU 1803.929 61.607 9.774 1403 N CYS 181 3.359 59.669 8.750 1404 CA CYS 1812.607 59.166 9.853 1405 CB CYS 181 1.081 59.240 9.646 1406 SG CYS 1810.320 57.652 9.235 1407 C CYS 181 3.033 57.745 9.969 1408 O CYS 1813.775 57.264 9.115 1409 N GLU 182 2.610 57.046 11.041 1410 CA GLU 1822.773 55.626 11.145 1411 CB GLU 182 4.182 55.141 11.597 1412 CG GLU 1824.548 53.747 11.061 1413 CD GLU 182 5.459 52.996 12.037 1414 OE1 GLU 1826.063 53.632 12.943 1415 OE2 GLU 182 5.557 51.752 11.873 1416 C GLU 1821.817 55.215 12.203 1417 O GLU 182 1.768 55.808 13.279 1418 N ILE 1831.016 54.181 11.917 1419 CA ILE 183 0.319 53.547 12.988 1420 CB ILE 183−1.114 53.216 12.634 1421 CG2 ILE 183 −1.729 52.377 13.770 1422 CG1 ILE183 −1.886 54.517 12.321 1423 CD1 ILE 183 −2.950 54.385 11.234 1424 CILE 183 1.110 52.291 13.218 1425 O ILE 183 1.944 51.931 12.388 1426 NGLN 184 0.918 51.623 14.373 1427 CA GLN 184 1.757 50.497 14.624 1428 CBGLN 184 2.855 50.773 15.659 1429 CG GLN 184 4.135 49.982 15.378 1430 CDGLN 184 5.127 50.174 16.528 1431 OE1 GLN 184 4.754 50.294 17.693 1432NE2 GLN 184 6.437 50.199 16.184 1433 C GLN 184 0.914 49.364 15.107 1434O GLN 184 0.124 48.814 14.346 1435 N ASN 185 1.089 48.983 16.397 1436 CAASN 185 0.536 47.799 17.004 1437 CB ASN 185 −0.875 47.389 16.459 1438 CGASN 185 −0.906 46.154 15.555 1439 OD1 ASN 185 −1.089 45.034 16.020 1440ND2 ASN 185 −0.814 46.349 14.214 1441 C ASN 185 1.579 46.722 16.873 1442O ASN 185 2.530 46.919 16.116 1443 N PRO 186 1.488 45.619 17.589 1444 CAPRO 186 2.589 44.697 17.722 1445 CD PRO 186 0.564 45.505 18.703 1446 CBPRO 186 2.062 43.564 18.598 1447 CG PRO 186 0.982 44.235 19.478 1448 CPRO 186 3.127 44.282 16.390 1449 O PRO 186 2.338 43.881 15.535 1450 NALA 187 4.457 44.438 16.209 1451 CA ALA 187 5.073 44.859 14.981 1452 CBALA 187 6.580 44.539 14.905 1453 C ALA 187 4.404 44.235 13.798 1454 OALA 187 4.536 43.038 13.539 1455 N SER 188 3.669 45.088 13.054 1456 CASER 188 3.029 44.779 11.813 1457 CB SER 188 1.859 43.780 11.942 1458 OGSER 188 1.091 43.753 10.746 1459 C SER 188 2.445 46.090 11.394 1460 OSER 188 1.242 46.328 11.524 1461 N ALA 189 3.300 47.010 10.910 1462 CAALA 189 2.778 48.308 10.624 1463 CB ALA 189 3.416 49.425 11.456 1464 CALA 189 3.042 48.614 9.189 1465 O ALA 189 3.898 47.996 8.554 1466 N ASN190 2.281 49.596 8.663 1467 CA ASN 190 2.577 50.229 7.415 1468 CB ASN190 1.403 50.153 6.407 1469 CG ASN 190 1.384 48.768 5.744 1470 OD1 ASN190 0.623 47.880 6.111 1471 ND2 ASN 190 2.260 48.582 4.724 1472 C ASN190 2.837 51.674 7.745 1473 O ASN 190 3.192 52.001 8.879 1474 N ARG 1912.701 52.605 6.775 1475 CA ARG 191 2.885 53.995 7.124 1476 CB ARG 1914.250 54.589 6.715 1477 CG ARG 191 5.459 53.903 7.328 1478 CD ARG 1916.764 54.292 6.641 1479 NE ARG 191 7.852 53.568 7.363 1480 CZ ARG 1918.935 54.265 7.818 1481 NH1 ARG 191 9.063 55.593 7.560 1482 NH2 ARG 1919.889 53.597 8.542 1483 C ARG 191 1.854 54.803 6.408 1484 O ARG 1910.708 54.392 6.289 1485 N SER 192 2.240 55.994 5.915 1486 CA SER 1921.280 56.783 5.192 1487 CB SER 192 0.524 57.823 6.045 1488 OG SER 1921.354 58.944 6.290 1489 C SER 192 1.974 57.561 4.123 1490 O SER 1923.075 57.223 3.683 1491 N ASP 193 1.290 58.632 3.655 1492 CA ASP 1931.747 59.381 2.527 1493 CB ASP 193 0.685 59.679 1.436 1494 CG ASP 193−0.381 60.641 1.982 1495 OD1 ASP 193 −1.123 61.210 1.136 1496 OD2 ASP193 −0.485 60.831 3.223 1497 C ASP 193 2.284 60.682 2.994 1498 O ASP 1931.958 61.206 4.056 1499 N PRO 194 3.185 61.139 2.176 1500 CA PRO 1944.166 62.056 2.672 1501 CD PRO 194 3.730 60.245 1.178 1502 CB PRO 1945.512 61.633 2.086 1503 CG PRO 194 5.249 60.278 1.410 1504 C PRO 1943.787 63.440 2.295 1505 O PRO 194 4.037 63.829 1.153 1506 N VAL 1953.172 64.206 3.224 1507 CA VAL 195 2.811 65.562 2.907 1508 CB VAL 1951.600 66.031 3.663 1509 CG1 VAL 195 0.550 64.930 3.532 1510 CG2 VAL 1951.998 66.335 5.111 1511 C VAL 195 3.987 66.412 3.278 1512 O VAL 1954.713 66.105 4.224 1513 N THR 196 4.265 67.490 2.512 1514 CA THR 1965.493 68.189 2.792 1515 CB THR 196 6.401 68.345 1.604 1516 OG1 THR 1967.533 69.131 1.974 1517 CG2 THR 196 5.625 69.037 0.483 1518 C THR 1965.148 69.562 3.229 1519 O THR 196 4.243 70.199 2.693 1520 N LEU 1975.888 70.082 4.217 1521 CA LEU 197 5.668 71.455 4.498 1522 CB LEU 1975.087 71.726 5.889 1523 CG LEU 197 3.586 72.015 5.786 1524 CD2 LEU 1972.969 72.292 7.162 1525 CD1 LEU 197 2.843 70.900 5.042 1526 C LEU 1976.951 72.182 4.387 1527 O LEU 197 7.926 71.918 5.091 1528 N ASN 1986.953 73.165 3.480 1529 CA ASN 198 7.872 74.238 3.628 1530 CB ASN 1988.532 74.695 2.315 1531 CG ASN 198 9.138 73.465 1.642 1532 OD1 ASN 19810.122 72.897 2.113 1533 ND2 ASN 198 8.514 73.035 0.525 1534 C ASN 1987.042 75.376 4.137 1535 O ASN 198 5.812 75.312 4.149 1536 N VAL 1997.694 76.454 4.601 1537 CA VAL 199 6.947 77.519 5.192 1538 CB VAL 1997.224 77.679 6.667 1539 CG1 VAL 199 8.157 76.546 7.124 1540 CG2 VAL 1997.889 79.036 6.913 1541 C VAL 199 7.388 78.763 4.506 1542 O VAL 1998.550 78.881 4.133 1543 N LEU 200 6.482 79.741 4.316 1544 CA LEU 2006.948 81.052 3.973 1545 CB LEU 200 6.217 81.766 2.813 1546 CG LEU 2006.828 83.149 2.490 1547 CD2 LEU 200 5.824 84.086 1.788 1548 CD1 LEU 2008.167 82.973 1.741 1549 C LEU 200 6.691 81.893 5.173 1550 O LEU 2005.898 81.536 6.042 1551 N TYR 201 7.363 83.054 5.233 1552 CA TYR 2017.174 83.982 6.300 1553 CB TYR 201 8.487 84.658 6.742 1554 CG TYR 2019.633 84.142 5.935 1555 CD1 TYR 201 10.195 84.959 4.985 1556 CD2 TYR 20110.144 82.877 6.091 1557 CE1 TYR 201 11.258 84.528 4.228 1558 CE2 TYR201 11.210 82.438 5.339 1559 CZ TYR 201 11.770 83.272 4.399 1560 OH TYR201 12.865 82.807 3.635 1561 C TYR 201 6.304 85.089 5.800 1562 O TYR 2015.878 85.101 4.643 1563 N GLY 202 6.075 86.067 6.698 1564 CA GLY 2025.742 87.396 6.317 1565 C GLY 202 6.479 88.254 7.302 1566 O GLY 2025.874 88.766 8.242 1567 N PRO 203 7.769 88.421 7.104 1568 CA PRO 2038.632 89.149 7.998 1569 CD PRO 203 8.505 87.717 6.064 1570 CB PRO 20310.069 88.908 7.560 1571 CG PRO 203 10.003 87.853 6.441 1572 C PRO 2038.359 90.613 7.933 1573 O PRO 203 7.251 91.080 8.299 1574 OXT PRO 2039.312 91.333 7.526

[0137] TABLE 3 Full coodinate set of domains N and A1 of human CECAM5(homology model) (1606 atoms, 203 amino acids) ANum AType RType RNum X YZ 1 N LYS 1 7.719 28.906 40.374 2 CA LYS 1 7.851 27.446 40.229 3 CB LYS1 6.809 26.734 41.091 4 CG LYS 1 5.441 27.413 41.027 5 CD LYS 1 4.49126.971 42.148 6 CE LYS 1 3.141 27.698 42.179 7 NZ LYS 1 2.197 26.99043.074 8 C LYS 1 7.678 26.990 38.826 9 O LYS 1 6.752 26.240 38.523 10 NLEU 2 8.629 27.425 37.973 11 CA LEU 2 9.051 26.761 36.779 12 CB LEU 210.019 25.616 37.140 13 CG LEU 2 10.513 24.754 35.969 14 CD2 LEU 210.784 23.313 36.435 15 CD1 LEU 2 11.710 25.411 35.264 16 C LEU 2 7.86826.210 36.040 17 O LEU 2 7.587 25.014 36.119 18 N THR 3 7.156 27.05535.272 19 CA THR 3 6.338 26.446 34.274 20 CB THR 3 4.867 26.351 34.59021 OG1 THR 3 4.354 27.606 34.995 22 CG2 THR 3 4.679 25.323 35.708 23 CTHR 3 6.420 27.222 33.016 24 O THR 3 7.485 27.542 32.485 25 N ILE 45.220 27.467 32.495 26 CA ILE 4 4.898 27.380 31.122 27 CB ILE 4 3.41427.094 31.056 28 CG2 ILE 4 2.817 27.645 32.362 29 CG1 ILE 4 2.706 27.58229.785 30 CD1 ILE 4 1.190 27.556 29.964 31 C ILE 4 5.299 28.670 30.50132 O ILE 4 5.731 29.607 31.167 33 N GLU 5 5.207 28.727 29.174 34 CA GLU5 5.406 29.948 28.488 35 CB GLU 5 6.776 30.023 27.796 36 CG GLU 5 7.27131.453 27.633 37 CD GLU 5 8.469 31.398 26.712 38 OE1 GLU 5 9.340 30.50626.885 39 OE2 GLU 5 8.525 32.280 25.814 40 C GLU 5 4.375 29.904 27.43341 O GLU 5 3.556 28.985 27.383 42 N SER 6 4.390 30.887 26.534 43 CA SER6 3.762 30.536 25.315 44 CB SER 6 2.220 30.413 25.400 45 OG SER 6 1.53231.447 24.712 46 C SER 6 4.248 31.483 24.282 47 O SER 6 4.588 32.63424.557 48 N THR 7 4.391 30.949 23.058 49 CA THR 7 5.185 31.571 22.043 50CB THR 7 6.530 30.916 21.987 51 OG1 THR 7 6.451 29.758 21.164 52 CG2 THR7 6.933 30.480 23.410 53 C THR 7 4.485 31.307 20.728 54 O THR 7 3.95030.213 20.561 55 N PRO 8 4.423 32.174 19.737 56 CA PRO 8 4.856 33.54819.726 57 CD PRO 8 3.905 31.742 18.448 58 CB PRO 8 4.784 34.016 18.26259 CG PRO 8 4.386 32.779 17.430 60 C PRO 8 3.967 34.410 20.576 61 O PRO8 2.756 34.386 20.370 62 N PHE 9 4.517 35.217 21.502 63 CA PHE 9 3.63636.141 22.162 64 CB PHE 9 4.197 36.770 23.438 65 CG PHE 9 5.659 36.53123.446 66 CD1 PHE 9 6.498 37.206 22.587 67 CD2 PHE 9 6.175 35.607 24.32468 CE1 PHE 9 7.851 36.969 22.600 69 CE2 PHE 9 7.527 35.370 24.338 70 CZPHE 9 8.361 36.044 23.480 71 C PHE 9 3.351 37.259 21.232 72 O PHE 94.192 37.642 20.427 73 N ASN 10 2.133 37.812 21.329 74 CA ASN 10 1.61438.674 20.328 75 CB ASN 10 2.538 39.860 20.000 76 CG ASN 10 2.564 40.74521.243 77 OD1 ASN 10 3.586 40.930 21.897 78 ND2 ASN 10 1.372 41.28521.600 79 C ASN 10 1.397 37.814 19.137 80 O ASN 10 2.324 37.199 18.61281 N VAL 11 0.130 37.708 18.714 82 CA VAL 11 −0.190 36.730 17.724 83 CBVAL 11 −0.948 35.575 18.295 84 CG1 VAL 11 −1.005 34.472 17.231 85 CG2VAL 11 −0.295 35.190 19.634 86 C VAL 11 −1.071 37.388 16.724 87 O VAL 11−1.905 38.221 17.071 88 N ALA 12 −0.909 37.024 15.442 89 CA ALA 12−1.746 37.630 14.455 90 CB ALA 12 −1.049 37.835 13.107 91 C ALA 12−2.899 36.724 14.214 92 O ALA 12 −2.978 35.630 14.760 93 N GLU 13 −3.82837.182 13.360 94 CA GLU 13 −4.929 36.381 12.938 95 CB GLU 13 −6.06737.242 12.386 96 CG GLU 13 −7.406 37.104 13.096 97 CD GLU 13 −8.42637.618 12.105 98 OE1 GLU 13 −9.337 38.373 12.545 99 OE2 GLU 13 −8.29337.268 10.905 100 C GLU 13 −4.438 35.561 11.785 101 O GLU 13 −3.72136.063 10.922 102 N GLY 14 −4.824 34.273 11.726 103 CA GLY 14 −4.46833.488 10.576 104 C GLY 14 −3.074 32.980 10.767 105 O GLY 14 −2.52632.273 9.920 106 N LYS 15 −2.451 33.327 11.904 107 CA LYS 15 −1.19732.718 12.217 108 CB LYS 15 −0.051 33.735 12.269 109 CG LYS 15 −0.11934.632 11.029 110 CD LYS 15 0.993 35.679 10.902 111 CE LYS 15 2.13135.267 9.963 112 NZ LYS 15 2.956 34.221 10.607 113 C LYS 15 −1.39132.076 13.547 114 O LYS 15 −2.304 32.432 14.292 115 N GLU 16 −0.56531.062 13.858 116 CA GLU 16 −0.885 30.231 14.973 117 CB GLU 16 −0.46828.759 14.821 118 CG GLU 16 −0.855 28.083 13.509 119 CD GLU 16 0.05526.879 13.339 120 OE1 GLU 16 −0.468 25.736 13.272 121 OE2 GLU 16 1.29527.094 13.279 122 C GLU 16 −0.106 30.692 16.151 123 O GLU 16 0.36031.825 16.221 124 N VAL 17 0.040 29.750 17.100 125 CA VAL 17 0.90129.883 18.234 126 CB VAL 17 0.168 30.218 19.485 127 CG1 VAL 17 0.93831.330 20.220 128 CG2 VAL 17 −1.281 30.575 19.115 129 C VAL 17 1.42528.531 18.506 130 O VAL 17 1.137 27.562 17.804 131 N LEU 18 2.194 28.44019.598 132 CA LEU 18 2.312 27.209 20.293 133 CB LEU 18 3.640 26.46820.079 134 CG LEU 18 3.893 25.416 21.171 135 CD2 LEU 18 5.356 24.94521.148 136 CD1 LEU 18 2.881 24.263 21.105 137 C LEU 18 2.260 27.57821.730 138 O LEU 18 2.724 28.648 22.126 139 N LEU 19 1.677 26.706 22.551140 CA LEU 19 1.716 26.993 23.941 141 CB LEU 19 0.403 26.655 24.656 142CG LEU 19 −0.680 27.738 24.442 143 CD2 LEU 19 −0.640 28.282 23.002 144CD1 LEU 19 −0.585 28.822 25.521 145 C LEU 19 2.805 26.150 24.477 146 OLEU 19 2.745 24.919 24.382 147 N LEU 20 3.856 26.783 25.021 148 CA LEU20 4.993 26.013 25.422 149 CB LEU 20 6.326 26.772 25.259 150 CG LEU 207.534 25.943 24.767 151 CD2 LEU 20 8.836 26.766 24.803 152 CD1 LEU 207.278 25.353 23.369 153 C LEU 20 4.841 25.737 26.873 154 O LEU 20 4.67726.668 27.660 155 N VAL 21 4.936 24.462 27.288 156 CA VAL 21 5.23824.258 28.671 157 CB VAL 21 4.507 23.108 29.315 158 CG1 VAL 21 5.35022.512 30.458 159 CG2 VAL 21 3.139 23.628 29.800 160 C VAL 21 6.69423.965 28.679 161 O VAL 21 7.215 23.442 27.698 162 N HIS 22 7.397 24.32129.761 163 CA HIS 22 8.786 24.010 29.781 164 ND1 HIS 22 9.333 26.49628.441 165 CG HIS 22 9.558 26.351 29.789 166 CB HIS 22 9.645 25.04830.483 167 NE2 HIS 22 9.498 28.548 29.294 168 CD2 HIS 22 9.653 27.61230.296 169 CE1 HIS 22 9.307 27.836 28.202 170 C HIS 22 8.920 22.79330.582 171 O HIS 22 8.305 21.766 30.305 172 N ASN 23 9.748 22.904 31.629173 CA ASN 23 10.006 21.784 32.467 174 CB ASN 23 11.195 22.015 33.403175 CG ASN 23 12.353 22.416 32.510 176 OD1 ASN 23 12.364 23.492 31.918177 ND2 ASN 23 13.354 21.506 32.387 178 C ASN 23 8.801 21.518 33.302 179O ASN 23 8.148 22.426 33.818 180 N LEU 24 8.508 20.219 33.461 181 CA LEU24 7.461 19.763 34.313 182 CB LEU 24 7.266 20.563 35.614 183 CG LEU 248.471 20.531 36.586 184 CD2 LEU 24 9.273 19.225 36.501 185 CD1 LEU 248.009 20.850 38.021 186 C LEU 24 6.178 19.720 33.563 187 O LEU 24 5.75520.754 33.046 188 N PRO 25 5.492 18.615 33.419 189 CA PRO 25 6.02417.290 33.582 190 CD PRO 25 4.799 18.618 32.147 191 CB PRO 25 6.66617.029 32.228 192 CG PRO 25 5.643 17.676 31.251 193 C PRO 25 6.73216.752 34.802 194 O PRO 25 7.442 17.427 35.540 195 N GLN 26 6.552 15.45135.055 196 CA GLN 26 7.306 14.839 36.100 197 CB GLN 26 7.191 15.52637.471 198 CG GLN 26 8.493 15.518 38.270 199 CD GLN 26 8.277 16.29239.569 200 OE1 GLN 26 8.593 15.744 40.622 201 NE2 GLN 26 7.767 17.55339.529 202 C GLN 26 6.699 13.501 36.286 203 O GLN 26 6.592 13.016 37.410204 N HIS 27 6.271 12.876 35.172 205 CA HIS 27 5.746 11.550 35.271 206ND1 HIS 27 6.880 8.446 34.776 207 CG HIS 27 6.598 9.177 35.914 208 CBHIS 27 6.747 10.661 36.032 209 NE2 HIS 27 6.350 6.985 36.369 210 CD2 HIS27 6.263 8.281 36.864 211 CE1 HIS 27 6.719 7.141 35.109 212 C HIS 274.449 11.684 36.019 213 O HIS 27 4.406 11.513 37.237 214 N LEU 28 3.36212.053 35.294 215 CA LEU 28 2.137 12.488 35.925 216 CB LEU 28 1.42913.680 35.242 217 CG LEU 28 1.843 15.128 35.603 218 CD2 LEU 28 3.20615.527 35.022 219 CD1 LEU 28 1.751 15.391 37.104 220 C LEU 28 1.13511.398 35.752 221 O LEU 28 1.389 10.229 36.038 222 N PHE 29 −0.05611.813 35.284 223 CA PHE 29 −1.120 10.941 34.905 224 CB PHE 29 −2.18010.728 35.999 225 CG PHE 29 −3.017 9.531 35.649 226 CD1 PHE 29 −3.3638.646 36.641 227 CD2 PHE 29 −3.470 9.300 34.370 228 CE1 PHE 29 −4.1157.537 36.341 229 CE2 PHE 29 −4.226 8.197 34.061 230 CZ PHE 29 −4.5457.306 35.058 231 C PHE 29 −1.812 11.629 33.772 232 O PHE 29 −1.55811.322 32.609 233 N GLY 30 −2.725 12.571 34.083 234 CA GLY 30 −3.55813.104 33.048 235 C GLY 30 −3.063 14.471 32.693 236 O GLY 30 −2.61915.252 33.535 237 N TYR 31 −3.140 14.817 31.401 238 CA TYR 31 −2.86716.188 31.120 239 CB TYR 31 −2.000 16.431 29.876 240 CG TYR 31 −0.76915.562 29.727 241 CD1 TYR 31 0.219 16.026 28.890 242 CD2 TYR 31 −0.55814.350 30.345 243 CE1 TYR 31 1.370 15.319 28.662 244 CE2 TYR 31 0.60613.619 30.130 245 CZ TYR 31 1.569 14.108 29.281 246 OH TYR 31 2.77113.397 29.034 247 C TYR 31 −4.204 16.843 30.881 248 O TYR 31 −5.22116.382 31.405 249 N SER 32 −4.220 17.929 30.067 250 CA SER 32 −5.40418.590 29.575 251 CB SER 32 −6.637 18.522 30.497 252 OG SER 32 −7.79018.998 29.815 253 C SER 32 −5.091 20.047 29.385 254 O SER 32 −4.14620.569 29.977 255 N TRP 33 −5.889 20.742 28.541 256 CA TRP 33 −5.88422.181 28.518 257 CB TRP 33 −5.461 22.830 27.199 258 CG TRP 33 −3.97522.934 27.032 259 CD2 TRP 33 −3.130 23.860 27.742 260 CD1 TRP 33 −3.15722.181 26.246 261 NE1 TRP 33 −1.852 22.575 26.424 262 CE2 TRP 33 −1.82123.605 27.349 263 CE3 TRP 33 −3.421 24.840 28.640 264 CZ2 TRP 33 −0.77824.335 27.863 265 CZ3 TRP 33 −2.378 25.578 29.161 266 CH2 TRP 33 −1.07325.322 28.777 267 C TRP 33 −7.293 22.626 28.715 268 O TRP 33 −8.23621.906 28.386 269 N TYR 34 −7.470 23.837 29.268 270 CA TYR 34 −8.80824.294 29.477 271 CB TYR 34 −9.114 24.572 30.958 272 CG TYR 34 −9.20023.225 31.580 273 CD1 TYR 34 −8.092 22.664 32.159 274 CD2 TYR 34 −10.36222.504 31.566 275 CE1 TYR 34 −8.149 21.410 32.723 276 CE2 TYR 34 −10.43621.250 32.126 277 CZ TYR 34 −9.319 20.705 32.707 278 OH TYR 34 −9.37719.417 33.283 279 C TYR 34 −8.973 25.556 28.713 280 O TYR 34 −8.64625.627 27.532 281 N LYS 35 −9.513 26.588 29.382 282 CA LYS 35 −9.69127.840 28.725 283 CB LYS 35 −10.549 27.741 27.456 284 CG LYS 35 −10.98129.102 26.904 285 CD LYS 35 −11.233 29.098 25.395 286 CE LYS 35 −11.50430.491 24.810 287 NZ LYS 35 −12.737 30.467 23.993 288 C LYS 35 −10.40128.746 29.668 289 O LYS 35 −11.552 28.522 30.027 290 N GLY 36 −9.73129.830 30.077 291 CA GLY 36 −10.439 30.860 30.769 292 C GLY 36 −10.62130.450 32.188 293 O GLY 36 −11.690 30.641 32.759 294 N GLU 37 −9.55829.915 32.807 295 CA GLU 37 −9.452 29.961 34.236 296 CB GLU 37 −10.05131.257 34.851 297 CG GLU 37 −9.611 31.529 36.290 298 CD GLU 37 −10.25832.831 36.731 299 OE1 GLU 37 −10.177 33.163 37.949 300 OE2 GLU 37−10.861 33.507 35.858 301 C GLU 37 −10.179 28.788 34.779 302 O GLU 37−9.554 27.860 35.289 303 N ARG 38 −11.518 28.853 34.647 304 CA ARG 38−12.481 27.903 35.102 305 CB ARG 38 −13.756 27.956 34.270 306 CG ARG 38−14.995 27.473 35.005 307 CD ARG 38 −16.249 28.264 34.634 308 NE ARG 38−17.400 27.579 35.298 309 CZ ARG 38 −18.435 27.078 34.556 310 NH1 ARG 38−19.407 26.336 35.156 311 NH2 ARG 38 −18.476 27.296 33.213 312 C ARG 38−11.902 26.542 34.972 313 O ARG 38 −11.222 26.228 33.994 314 N VAL 39−12.079 25.712 36.009 315 CA VAL 39 −11.295 24.521 36.063 316 CB VAL 39−10.553 24.438 37.376 317 CG1 VAL 39 −9.800 23.109 37.476 318 CG2 VAL 39−9.608 25.649 37.419 319 C VAL 39 −12.234 23.384 35.852 320 O VAL 39−11.866 22.211 35.905 321 N ASP 40 −13.490 23.723 35.512 322 CA ASP 40−14.369 22.729 34.972 323 CB ASP 40 −15.738 23.260 34.507 324 CG ASP 40−16.828 22.975 35.530 325 OD1 ASP 40 −17.988 23.384 35.260 326 OD2 ASP40 −16.539 22.373 36.595 327 C ASP 40 −13.717 22.196 33.735 328 O ASP 40−12.725 22.740 33.248 329 N GLY 41 −14.310 21.124 33.186 330 CA GLY 41−14.070 20.709 31.847 331 C GLY 41 −15.419 20.721 31.221 332 O GLY 41−15.694 19.949 30.298 333 N ASN 42 −16.284 21.603 31.763 334 CA ASN 42−17.509 22.027 31.156 335 CB ASN 42 −17.882 23.429 31.655 336 CG ASN 42−19.385 23.645 31.645 337 OD1 ASN 42 −19.989 24.062 30.664 338 ND2 ASN42 −20.000 23.396 32.826 339 C ASN 42 −17.177 22.150 29.716 340 O ASN 42−17.755 21.488 28.854 341 N ARG 43 −16.125 22.944 29.459 342 CA ARG 43−15.396 22.778 28.251 343 CB ARG 43 −15.167 24.088 27.473 344 CG ARG 43−16.125 24.322 26.291 345 CD ARG 43 −16.800 23.049 25.766 346 NE ARG 43−18.278 23.258 25.720 347 CZ ARG 43 −18.880 24.090 24.821 348 NH1 ARG 43−20.230 23.989 24.629 349 NH2 ARG 43 −18.154 24.999 24.107 350 C ARG 43−14.066 22.244 28.662 351 O ARG 43 −13.178 22.986 29.074 352 N GLN 44−13.904 20.912 28.547 353 CA GLN 44 −12.596 20.335 28.529 354 CB GLN 44−12.472 18.930 29.162 355 CG GLN 44 −11.057 18.343 29.031 356 CD GLN 44−10.957 17.047 29.833 357 OE1 GLN 44 −10.677 17.045 31.037 358 NE2 GLN44 −11.170 15.894 29.148 359 C GLN 44 −12.243 20.199 27.087 360 O GLN 44−13.030 19.697 26.281 361 N ILE 45 −11.030 20.685 26.756 362 CA ILE 45−10.515 20.589 25.429 363 CB ILE 45 −9.363 21.505 25.173 364 CG2 ILE 45−8.943 21.341 23.693 365 CG1 ILE 45 −9.715 22.928 25.614 366 CD1 ILE 45−10.508 23.725 24.578 367 C ILE 45 −9.919 19.248 25.352 368 O ILE 45−10.516 18.297 24.853 369 N ILE 46 −8.680 19.176 25.854 370 CA ILE 46−7.699 18.254 25.372 371 CB ILE 46 −6.516 19.040 24.847 372 CG2 ILE 46−6.593 20.414 25.527 373 CG1 ILE 46 −5.141 18.373 25.000 374 CD1 ILE 46−4.148 19.217 25.806 375 C ILE 46 −7.316 17.365 26.511 376 O ILE 46−7.729 17.594 27.644 377 N GLY 47 −6.540 16.297 26.250 378 CA GLY 47−6.033 15.577 27.382 379 C GLY 47 −5.301 14.373 26.904 380 O GLY 47−5.776 13.248 27.041 381 N TYR 48 −4.095 14.588 26.355 382 CA TYR 48−3.188 13.500 26.194 383 CB TYR 48 −1.829 14.024 25.688 384 CG TYR 48−0.740 13.008 25.796 385 CD1 TYR 48 −0.042 12.877 26.977 386 CD2 TYR 48−0.419 12.203 24.719 387 CE1 TYR 48 0.960 11.956 27.083 388 CE2 TYR 480.594 11.276 24.828 389 CZ TYR 48 1.275 11.165 26.016 390 OH TYR 482.315 10.231 26.164 391 C TYR 48 −3.054 12.901 27.561 392 O TYR 48−3.286 13.570 28.574 393 N VAL 49 −2.728 11.600 27.610 394 CA VAL 49−2.791 10.785 28.789 395 CB VAL 49 −3.659 9.579 28.537 396 CG1 VAL 49−3.734 8.740 29.820 397 CG2 VAL 49 −5.015 10.031 27.946 398 C VAL 49−1.402 10.253 28.972 399 O VAL 49 −0.806 9.761 28.017 400 N ILE 50−0.803 10.318 30.172 401 CA ILE 50 0.506 9.738 30.149 402 CB ILE 501.517 10.415 31.029 403 CG2 ILE 50 1.313 10.066 32.518 404 CG1 ILE 502.916 10.112 30.472 405 CD1 ILE 50 3.893 11.267 30.638 406 C ILE 500.374 8.309 30.550 407 O ILE 50 −0.661 7.910 31.078 408 N GLY 51 1.4197.496 30.283 409 CA GLY 51 1.374 6.094 30.588 410 C GLY 51 0.998 5.38629.328 411 O GLY 51 1.574 5.642 28.268 412 N THR 52 0.012 4.462 29.407413 CA THR 52 −0.538 3.959 28.185 414 CB THR 52 −1.699 3.003 28.313 415OG1 THR 52 −2.386 2.890 27.070 416 CG2 THR 52 −2.645 3.511 29.407 417 CTHR 52 −1.019 5.175 27.500 418 O THR 52 −1.973 5.825 27.926 419 N GLN 53−0.304 5.554 26.441 420 CA GLN 53 −0.474 6.876 25.940 421 CB GLN 530.777 7.409 25.241 422 CG GLN 53 2.065 7.273 26.041 423 CD GLN 53 3.1767.794 25.145 424 OE1 GLN 53 4.148 8.342 25.657 425 NE2 GLN 53 3.0447.644 23.798 426 C GLN 53 −1.550 6.826 24.921 427 O GLN 53 −1.925 5.76624.425 428 N GLN 54 −2.084 8.006 24.600 429 CA GLN 54 −3.267 8.10623.827 430 CB GLN 54 −4.337 7.090 24.292 431 CG GLN 54 −5.798 7.53424.351 432 CD GLN 54 −6.631 6.282 24.102 433 OE1 GLN 54 −7.828 6.27224.382 434 NE2 GLN 54 −6.003 5.204 23.547 435 C GLN 54 −3.681 9.48624.139 436 O GLN 54 −3.045 10.144 24.957 437 N ALA 55 −4.731 9.98023.480 438 CA ALA 55 −5.233 11.241 23.895 439 CB ALA 55 −4.719 12.43423.076 440 C ALA 55 −6.679 11.126 23.678 441 O ALA 55 −7.139 10.31622.878 442 N THR 56 −7.450 11.924 24.417 443 CA THR 56 −8.844 11.84324.199 444 CB THR 56 −9.468 10.781 25.060 445 OG1 THR 56 −10.885 10.86325.001 446 CG2 THR 56 −8.977 10.956 26.500 447 C THR 56 −9.352 13.19724.536 448 O THR 56 −9.126 13.713 25.627 449 N PRO 57 −10.009 13.82423.618 450 CA PRO 57 −10.504 15.141 23.833 451 CD PRO 57 −10.444 13.24322.361 452 CB PRO 57 −11.009 15.642 22.493 453 CG PRO 57 −10.926 14.44421.524 454 C PRO 57 −11.677 15.013 24.719 455 O PRO 57 −11.837 13.98825.379 456 N GLY 58 −12.583 15.985 24.607 457 CA GLY 58 −13.892 15.56224.249 458 C GLY 58 −14.574 16.748 23.658 459 O GLY 58 −14.795 16.84322.453 460 N PRO 59 −14.970 17.613 24.537 461 CA PRO 59 −16.211 18.26724.255 462 CD PRO 59 −14.781 17.352 25.948 463 CB PRO 59 −16.980 18.33525.576 464 CG PRO 59 −16.177 17.495 26.572 465 C PRO 59 −15.992 19.61023.670 466 O PRO 59 −16.962 20.223 23.230 467 N ALA 60 −14.772 20.14623.709 468 CA ALA 60 −14.675 21.558 23.517 469 CB ALA 60 −13.802 22.26224.574 470 C ALA 60 −14.074 21.831 22.183 471 O ALA 60 −13.905 20.91621.378 472 N TYR 61 −13.767 23.120 21.916 473 CA TYR 61 −13.358 23.50020.593 474 CB TYR 61 −13.036 24.986 20.415 475 CG TYR 61 −13.922 25.54119.333 476 CD1 TYR 61 −14.819 24.718 18.683 477 CD2 TYR 61 −13.86026.861 18.944 478 CE1 TYR 61 −15.636 25.221 17.696 479 CE2 TYR 61−14.672 27.377 17.955 480 CZ TYR 61 −15.566 26.541 17.337 481 OH TYR 61−16.402 27.059 16.322 482 C TYR 61 −12.143 22.717 20.279 483 O TYR 61−11.122 22.775 20.968 484 N SER 62 −12.275 21.911 19.220 485 CA SER 62−11.235 21.040 18.797 486 CB SER 62 −11.539 19.572 19.126 487 OG SER 62−10.354 18.785 19.095 488 C SER 62 −11.247 21.184 17.325 489 O SER 62−11.267 20.209 16.579 490 N GLY 63 −11.272 22.452 16.882 491 CA GLY 63−11.314 22.771 15.492 492 C GLY 63 −9.907 22.787 15.017 493 O GLY 63−9.597 22.303 13.930 494 N ARG 64 −8.998 23.354 15.826 495 CA ARG 64−7.643 23.306 15.383 496 CB ARG 64 −7.302 24.362 14.324 497 CG ARG 64−8.503 25.211 13.925 498 CD ARG 64 −8.355 26.687 14.299 499 NE ARG 64−9.721 27.254 14.413 500 CZ ARG 64 −10.274 27.433 15.654 501 NH1 ARG 64−9.535 27.196 16.765 502 NH2 ARG 64 −11.578 27.838 15.762 503 C ARG 64−6.757 23.529 16.556 504 O ARG 64 −6.195 24.609 16.724 505 N GLU 65−6.591 22.487 17.387 506 CA GLU 65 −5.559 22.529 18.371 507 CB GLU 65−6.013 23.127 19.711 508 CG GLU 65 −6.478 24.583 19.539 509 CD GLU 65−7.387 24.950 20.697 510 OE1 GLU 65 −8.127 24.041 21.165 511 OE2 GLU 65−7.341 26.124 21.150 512 C GLU 65 −5.110 21.125 18.562 513 O GLU 65−5.672 20.196 17.987 514 N ILE 66 −4.038 20.939 19.349 515 CA ILE 66−3.394 19.671 19.346 516 CB ILE 66 −2.404 19.552 18.218 517 CG2 ILE 66−1.675 18.200 18.308 518 CG1 ILE 66 −3.121 19.747 16.876 519 CD1 ILE 66−2.147 19.793 15.697 520 C ILE 66 −2.655 19.565 20.642 521 O ILE 66−2.362 20.564 21.296 522 N ILE 67 −2.348 18.326 21.053 523 CA ILE 67−1.613 18.133 22.256 524 CB ILE 67 −2.118 16.958 23.049 525 CG2 ILE 67−2.316 15.793 22.062 526 CG1 ILE 67 −1.231 16.627 24.270 527 CD1 ILE 67−0.957 17.852 25.153 528 C ILE 67 −0.198 17.885 21.869 529 O ILE 670.110 17.562 20.722 530 N TYR 68 0.700 18.071 22.848 531 CA TYR 68 2.05617.642 22.752 532 CB TYR 68 3.077 18.790 22.764 533 CG TYR 68 3.09419.298 21.375 534 CD1 TYR 68 4.056 18.852 20.501 535 CD2 TYR 68 2.13320.186 20.952 536 CE1 TYR 68 4.092 19.298 19.204 537 CE2 TYR 68 2.16920.631 19.655 538 CZ TYR 68 3.139 20.195 18.786 539 OH TYR 68 3.15520.671 17.462 540 C TYR 68 2.340 16.855 23.975 541 O TYR 68 2.003 17.24925.087 542 N PRO 69 2.982 15.742 23.796 543 CA PRO 69 3.351 14.88224.878 544 CD PRO 69 2.957 15.059 22.508 545 CB PRO 69 4.119 13.72824.220 546 CG PRO 69 3.591 13.679 22.771 547 C PRO 69 4.145 15.62925.916 548 O PRO 69 4.104 15.249 27.084 549 N ASN 70 4.878 16.687 25.534550 CA ASN 70 5.619 17.408 26.530 551 CB ASN 70 6.900 18.073 25.991 552CG ASN 70 6.661 18.462 24.544 553 OD1 ASN 70 7.480 18.152 23.679 554 ND2ASN 70 5.529 19.168 24.266 555 C ASN 70 4.718 18.483 27.053 556 O ASN 705.168 19.560 27.437 557 N ALA 71 3.406 18.183 27.095 558 CA ALA 71 2.39019.057 27.620 559 CB ALA 71 2.360 19.107 29.157 560 C ALA 71 2.56220.443 27.083 561 O ALA 71 2.860 21.388 27.817 562 N SER 72 2.334 20.58725.764 563 CA SER 72 2.188 21.856 25.111 564 CB SER 72 3.389 22.23724.219 565 OG SER 72 4.387 22.911 24.977 566 C SER 72 1.010 21.69524.193 567 O SER 72 0.763 20.596 23.696 568 N LEU 73 0.242 22.778 23.954569 CA LEU 73 −0.879 22.699 23.052 570 CB LEU 73 −2.179 23.278 23.686571 CG LEU 73 −3.456 23.390 22.803 572 CD2 LEU 73 −4.212 24.686 23.145573 CD1 LEU 73 −4.379 22.166 22.939 574 C LEU 73 −0.515 23.523 21.859575 O LEU 73 0.049 24.605 22.009 576 N LEU 74 −0.813 23.051 20.634 577CA LEU 74 −0.753 23.987 19.556 578 CB LEU 74 −0.459 23.377 18.167 579 CGLEU 74 −0.369 24.407 17.009 580 CD2 LEU 74 −0.948 23.849 15.698 581 CD1LEU 74 1.063 24.937 16.824 582 C LEU 74 −2.117 24.539 19.488 583 O LEU74 −3.078 23.842 19.808 584 N ILE 75 −2.246 25.803 19.071 585 CA ILE 75−3.554 26.214 18.683 586 CB ILE 75 −4.171 27.263 19.568 587 CG2 ILE 75−3.053 28.151 20.117 588 CG1 ILE 75 −5.267 28.025 18.803 589 CD1 ILE 75−5.831 29.221 19.571 590 C ILE 75 −3.414 26.763 17.308 591 O ILE 75−2.697 27.739 17.083 592 N GLN 76 −4.090 26.117 16.348 593 CA GLN 76−4.018 26.609 15.010 594 CB GLN 76 −4.523 25.614 13.949 595 CG GLN 76−4.362 24.151 14.349 596 CD GLN 76 −4.521 23.334 13.072 597 OE1 GLN 76−5.516 22.639 12.888 598 NE2 GLN 76 −3.514 23.429 12.164 599 C GLN 76−4.863 27.830 14.955 600 O GLN 76 −5.039 28.504 15.968 601 N ASN 77−5.373 28.156 13.750 602 CA ASN 77 −5.716 29.507 13.419 603 CB ASN 77−6.312 29.693 12.014 604 CG ASN 77 −5.504 28.832 11.058 605 OD1 ASN 77−5.818 27.657 10.868 606 ND2 ASN 77 −4.454 29.419 10.426 607 C ASN 77−6.688 30.001 14.423 608 O ASN 77 −7.542 29.257 14.900 609 N ILE 78−6.515 31.264 14.828 610 CA ILE 78 −7.064 31.677 16.076 611 CB ILE 78−6.009 32.356 16.891 612 CG2 ILE 78 −6.669 33.043 18.090 613 CG1 ILE 78−4.926 31.329 17.274 614 CD1 ILE 78 −3.507 31.901 17.321 615 C ILE 78−8.169 32.652 15.811 616 O ILE 78 −9.342 32.364 16.037 617 N ILE 79−7.796 33.851 15.342 618 CA ILE 79 −8.635 35.014 15.352 619 CB ILE 79−9.868 34.983 14.482 620 CG2 ILE 79 −9.814 33.762 13.558 621 CG1 ILE 79−11.142 35.046 15.350 622 CD1 ILE 79 −12.423 35.382 14.575 623 C ILE 79−9.060 35.324 16.753 624 O ILE 79 −9.075 34.467 17.642 625 N GLN 80−9.393 36.616 16.960 626 CA GLN 80 −9.561 37.230 18.243 627 CB GLN 80−10.009 38.698 18.136 628 CG GLN 80 −11.449 38.940 18.593 629 CD GLN 80−11.999 40.144 17.839 630 OE1 GLN 80 −13.138 40.522 18.082 631 NE2 GLN80 −11.185 40.762 16.940 632 C GLN 80 −10.574 36.479 19.034 633 O GLN 80−10.653 36.642 20.251 634 N ASN 81 −11.381 35.636 18.361 635 CA ASN 81−12.413 34.888 19.028 636 CB ASN 81 −13.069 33.831 18.112 637 CG ASN 81−14.495 34.266 17.791 638 OD1 ASN 81 −15.215 33.606 17.048 639 ND2 ASN81 −14.919 35.418 18.365 640 C ASN 81 −11.769 34.152 20.162 641 O ASN 81−12.185 34.271 21.312 642 N ASP 82 −10.719 33.373 19.859 643 CA ASP 82−10.147 32.481 20.820 644 CB ASP 82 −9.376 31.358 20.114 645 CG ASP 82−10.396 30.646 19.234 646 OD1 ASP 82 −11.363 30.057 19.794 647 OD2 ASP82 −10.226 30.689 17.989 648 C ASP 82 −9.190 33.210 21.715 649 O ASP 82−8.625 32.610 22.627 650 N THR 83 −8.979 34.523 21.500 651 CA THR 83−8.001 35.201 22.298 652 CB THR 83 −7.825 36.650 21.953 653 OG1 THR 83−6.445 36.950 21.792 654 CG2 THR 83 −8.422 37.513 23.078 655 C THR 83−8.447 35.135 23.721 656 O THR 63 −9.637 34.995 24.005 657 N GLY 84−7.491 35.239 24.664 658 CA GLY 84 −7.883 35.251 26.036 659 C GLY 84−7.006 34.320 26.782 660 O GLY 84 −5.853 34.086 26.430 661 N PHE 85−7.555 33.774 27.872 662 CA PHE 85 −6.809 33.009 28.826 663 CB PHE 85−7.482 33.093 30.213 664 CG PHE 85 −6.716 32.415 31.303 665 CD1 PHE 85−5.416 32.718 31.625 666 CD2 PHE 85 −7.346 31.443 32.022 667 CE1 PHE 85−4.762 32.035 32.639 668 CE2 PHE 85 −6.724 30.755 33.045 669 CZ PHE 85−5.420 31.054 33.355 670 C PHE 85 −6.836 31.585 28.363 671 O PHE 85−7.721 31.158 27.617 672 N TYR 86 −5.848 30.803 28.816 673 CA TYR 86−5.996 29.388 28.853 674 CB TYR 86 −5.371 28.653 27.649 675 CG TYR 86−6.118 28.960 26.383 676 CD1 TYR 86 −5.478 29.586 25.342 677 CD2 TYR 86−7.440 28.607 26.201 678 CE1 TYR 86 −6.134 29.870 24.162 679 CE2 TYR 86−8.094 28.892 25.022 680 CZ TYR 86 −7.457 29.523 23.986 681 OH TYR 86−8.142 29.801 22.786 682 C TYR 86 −5.278 28.974 30.094 683 O TYR 86−4.324 29.622 30.529 684 N THE 87 −5.756 27.888 30.719 685 CA THR 87−5.156 27.393 31.919 686 CB THR 87 −6.115 27.319 33.062 687 OG1 THR 87−5.475 26.800 34.222 688 CG2 THR 87 −7.248 26.378 32.631 689 C THR 87−4.799 25.979 31.626 690 O THR 87 −5.218 25.434 30.608 691 N LEU 88−4.026 25.331 32.508 692 CA LEU 88 −3.703 23.972 32.208 693 CB LEU 88−2.288 23.815 31.629 694 CG LEU 88 −1.877 22.361 31.382 695 CD2 LEU 88−0.623 21.994 32.195 696 CD1 LEU 88 −1.744 22.064 29.872 697 C LEU 88−3.785 23.225 33.487 698 O LEU 88 −3.594 23.805 34.556 699 N HIS 89−4.126 21.927 33.407 700 CA HIS 89 −4.428 21.216 34.607 701 ND1 HIS 89−5.704 22.580 37.047 702 CG HIS 89 −6.295 21.582 36.309 703 CB HIS 89−5.932 21.198 34.917 704 NE2 HIS 89 −7.242 21.638 38.349 705 CD2 HIS 89−7.234 21.024 37.116 706 CE1 HIS 89 −6.308 22.569 38.266 707 C HIS 89−3.959 19.817 34.393 708 O HIS 89 −3.901 19.313 33.266 709 N VAL 90−3.522 19.175 35.490 710 CA VAL 90 −2.777 17.963 35.335 711 CB VAL 90−1.288 18.186 35.243 712 CG1 VAL 90 −0.749 17.563 33.944 713 CG2 VAL 90−1.042 19.696 35.361 714 C VAL 90 −3.016 17.151 36.550 715 O VAL 90−2.721 17.611 37.646 716 N ILE 91 −3.542 15.925 36.405 717 CA ILE 91−3.611 15.036 37.528 718 CB ILE 91 −4.501 13.849 37.243 719 CG2 ILE 91−4.710 13.022 38.539 720 CG1 ILE 91 −5.814 14.367 36.605 721 CD1 ILE 91−6.140 13.815 35.203 722 C ILE 91 −2.230 14.496 37.765 723 O ILE 91−1.325 14.625 36.941 724 N LYS 92 −2.043 13.884 38.942 725 CA LYS 92−1.495 12.574 39.052 726 CB LYS 92 0.002 12.440 39.429 727 CG LYS 920.904 13.670 39.306 728 CD LYS 92 2.314 13.457 39.896 729 CE LYS 923.380 14.448 39.396 730 NZ LYS 92 4.055 15.075 40.566 731 C LYS 92−2.193 11.998 40.217 732 O LYS 92 −2.948 12.698 40.882 733 N SER 93−1.963 10.710 40.519 734 CA SER 93 −2.577 10.255 41.717 735 CB SER 93−2.798 8.733 41.755 736 OG SER 93 −4.180 8.448 41.608 737 C SER 93−1.657 10.607 42.832 738 O SER 93 −0.859 9.777 43.263 739 N ASP 94−1.737 11.855 43.337 740 CA ASP 94 −1.038 12.125 44.564 741 CB ASP 940.464 11.801 44.538 742 CG ASP 94 0.740 11.161 45.890 743 OD1 ASP 941.220 9.992 45.909 744 OD2 ASP 94 0.441 11.818 46.922 745 C ASP 94−1.176 13.563 44.940 746 O ASP 94 −1.147 13.906 46.121 747 N LEU 95−1.321 14.455 43.949 748 CA LEU 95 −1.713 15.794 44.231 749 CB LEU 95−0.567 16.711 44.694 750 CG LEU 95 −0.988 17.819 45.698 751 CD2 LEU 95−1.637 17.222 46.956 752 CD1 LEU 95 −1.829 18.926 45.038 753 C LEU 95−2.130 16.299 42.913 754 O LEU 95 −1.542 15.937 41.896 755 N VAL 96−3.177 17.117 42.876 756 CA VAL 96 −3.505 17.607 41.595 757 CB VAL 96−4.978 17.649 41.406 758 CG1 VAL 96 −5.286 17.203 39.972 759 CG2 VAL 96−5.602 16.701 42.452 760 C VAL 96 −2.893 18.953 41.524 761 O VAL 96−2.832 19.689 42.511 762 N ASN 97 −2.345 19.297 40.352 763 CA ASN 97−1.682 20.552 40.286 764 CB ASN 97 −0.226 20.463 39.824 765 CG ASN 970.563 20.538 41.111 766 OD1 ASN 97 1.685 21.034 41.155 767 ND2 ASN 97−0.081 20.058 42.209 768 C ASN 97 −2.422 21.354 39.287 769 O ASN 97−3.246 20.819 38.546 770 N GLU 98 −2.162 22.668 39.243 771 CA GLU 98−2.777 23.418 38.196 772 CB GLU 98 −3.904 24.358 38.662 773 CG GLU 98−4.365 25.273 37.517 774 CD GLU 98 −5.864 25.548 37.595 775 OE1 GLU 98−6.442 25.943 36.550 776 OE2 GLU 98 −6.446 25.393 38.709 777 C GLU 98−1.715 24.278 37.656 778 O GLU 98 −1.142 23.968 36.610 779 N GLU 99−1.445 25.367 38.409 780 CA GLU 99 −0.702 26.542 38.074 781 CB GLU 990.542 26.788 38.916 782 CG GLU 99 1.320 27.911 38.247 783 CD GLU 992.633 28.034 38.977 784 OE1 GLU 99 3.147 26.980 39.440 785 OE2 GLU 993.137 29.186 39.093 786 C GLU 99 −0.249 26.535 36.656 787 O GLU 99 0.60225.750 36.245 788 N ALA 100 −0.841 27.454 35.886 789 CA ALA 100 −0.68227.394 34.480 790 CB ALA 100 −1.503 26.256 33.855 791 C ALA 100 −1.25328.669 33.984 792 O ALA 100 −2.342 28.693 33.413 793 N THR 101 −0.54229.784 34.218 794 CA THR 101 −1.001 31.041 33.727 795 CB THR 101 −0.69932.158 34.680 796 OG1 THR 101 −1.041 31.734 35.990 797 CG2 THR 101−1.506 33.415 34.303 798 C THR 101 −0.318 31.283 32.421 799 O THR 1010.668 30.622 32.094 800 N GLY 102 −0.846 32.217 31.615 801 CA GLY 102−0.335 32.374 30.283 802 C GLY 102 −1.485 32.838 29.451 803 O GLY 102−2.486 32.144 29.291 804 N GLN 103 −1.357 34.058 28.903 805 CA GLN 103−2.394 34.611 28.097 806 CB GLN 103 −3.087 35.797 28.792 807 CG GLN 103−4.049 36.626 27.942 808 CD GLN 103 −4.555 37.749 28.841 809 OE1 GLN 103−5.495 38.470 28.509 810 NE2 GLN 103 −3.908 37.906 30.024 811 C GLN 103−1.705 35.127 26.884 812 O GLN 103 −0.477 35.166 26.830 813 N PHE 104−2.474 35.540 25.865 814 CA PHE 104 −1.868 36.247 24.781 815 CB PHE 104−1.306 35.337 23.673 816 CG PHE 104 −2.423 34.461 23.239 817 CD1 PHE 104−2.635 33.255 23.871 818 CD2 PHE 104 −3.280 34.834 22.223 819 CE1 PHE104 −3.657 32.422 23.482 820 CE2 PHE 104 −4.302 33.996 21.839 821 CZ PHE104 −4.501 32.797 22.472 822 C PHE 104 −2.944 37.087 24.185 823 O PHE104 −4.071 37.115 24.676 824 N ARG 105 −2.623 37.806 23.100 825 CA ARG105 −3.641 38.575 22.463 826 CB ARG 105 −3.438 40.089 22.635 827 CG ARG105 −3.582 40.516 24.098 828 CD ARG 105 −2.503 41.485 24.573 829 NE ARG105 −3.003 42.070 25.847 830 CZ ARG 105 −2.314 43.078 26.457 831 NH1 ARG105 −2.706 43.477 27.701 832 NH2 ARG 105 −1.243 43.654 25.845 833 C ARG105 −3.599 38.231 21.013 834 O ARG 105 −2.685 37.544 20.556 835 N VAL106 −4.614 38.674 20.251 836 CA VAL 106 −4.529 38.444 18.845 837 CB VAL106 −5.655 37.653 18.289 838 CG1 VAL 106 −6.925 38.471 18.583 839 CG2VAL 106 −5.389 37.414 16.788 840 C VAL 106 −4.654 39.763 18.184 841 OVAL 106 −5.299 40.681 18.698 842 N TYR 107 −4.019 39.890 17.017 843 CATYR 107 −4.062 41.174 16.427 844 CB TYR 107 −2.740 41.935 16.635 845 CGTYR 107 −2.624 42.209 18.121 846 CD1 TYR 107 −1.740 41.509 18.921 847CD2 TYR 107 −3.389 43.172 18.742 848 CE1 TYR 107 −1.639 41.782 20.280849 CE2 TYR 107 −3.294 43.438 20.088 850 CZ TYR 107 −2.396 42.749 20.878851 OH TYR 107 −2.278 43.023 22.259 852 C TYR 107 −4.376 41.021 14.961853 O TYR 107 −4.153 39.992 14.332 854 N PRO 108 −4.968 42.095 14.492855 CA PRO 108 −5.712 42.110 13.262 856 CD PRO 108 −5.555 43.024 15.449857 CB PRO 108 −7.114 42.627 13.578 858 CG PRO 108 −7.016 43.207 15.010859 C PRO 108 −5.071 43.114 12.348 860 O PRO 108 −5.262 44.295 12.621861 N GLU 109 −4.342 42.665 11.303 862 CA GLU 109 −3.538 43.411 10.358863 CB GLU 109 −3.599 42.809 8.944 864 CG GLU 109 −3.634 41.279 8.941865 CD GLU 109 −5.058 40.813 9.202 866 OE1 GLU 109 −5.207 39.863 10.008867 OE2 GLU 109 −6.020 41.386 8.609 868 C GLU 109 −3.902 44.862 10.241869 O GLU 109 −5.071 45.245 10.284 870 N LEU 110 −2.886 45.733 10.044871 CA LEU 110 −3.172 47.139 10.113 872 CB LEU 110 −2.340 47.913 11.157873 CG LEU 110 −2.457 49.441 10.958 874 CD2 LEU 110 −1.150 50.137 11.358875 CD1 LEU 110 −3.724 50.034 11.606 876 C LEU 110 −2.950 47.832 8.795877 O LEU 110 −1.862 47.881 8.212 878 N PRO 111 −4.049 48.424 8.404 879CA PRO 111 −4.240 49.147 7.174 880 CD PRO 111 −5.283 48.142 9.107 881 CBPRO 111 −5.665 49.696 7.258 882 CG PRO 111 −6.393 48.836 8.309 883 C PRO111 −3.236 50.252 7.004 884 O PRO 111 −2.340 50.372 7.836 885 N LYS 112−3.365 51.061 5.933 886 CA LYS 112 −2.493 52.188 5.757 887 CB LYS 112−1.986 52.355 4.312 888 CG LYS 112 −0.931 53.449 4.153 889 CD LYS 112−0.515 53.718 2.706 890 CE LYS 112 0.409 54.931 2.584 891 NZ LYS 1121.242 54.825 1.365 892 C LYS 112 −3.281 53.402 6.087 893 O LYS 112−4.421 53.537 5.636 894 N PRO 113 −2.731 54.296 6.867 895 CA PRO 113−3.368 55.540 7.180 896 CD PRO 113 −1.526 54.065 7.634 897 CB PRO 113−2.642 56.125 8.393 898 CG PRO 113 −1.607 55.067 8.810 899 C PRO 113−3.216 56.431 5.991 900 O PRO 113 −2.464 56.090 5.075 901 N SER 114−3.914 57.580 5.998 902 CA SER 114 −3.648 58.574 5.006 903 CB SER 114−4.575 58.491 3.779 904 OG SER 114 −3.962 59.107 2.655 905 C SER 114−3.867 59.873 5.701 906 O SER 114 −4.841 60.023 6.438 907 N ILE 115−2.930 60.820 5.520 908 CA ILE 115 −2.909 61.986 6.338 909 CB ILE 115−1.541 62.255 6.870 910 CG2 ILE 115 −0.622 62.544 5.675 911 CG1 ILE 115−1.570 63.380 7.914 912 CD1 ILE 115 −0.283 64.194 7.924 913 C ILE 115−3.307 63.143 5.496 914 O ILE 115 −3.022 63.186 4.299 915 N SER 116−4.004 64.120 6.108 916 CA SER 116 −4.337 65.309 5.392 917 CB SER 116−5.856 65.530 5.240 918 OG SER 116 −6.131 66.570 4.311 919 C SER 116−3.775 66.452 6.175 920 O SER 116 −3.793 66.459 7.405 921 N SER 117−3.251 67.463 5.469 922 CA SER 117 −2.979 68.702 6.123 923 CB SER 117−1.490 69.078 6.160 924 OG SER 117 −1.371 70.466 6.432 925 C SER 117−3.660 69.737 5.305 926 O SER 117 −3.889 69.556 4.106 927 N ASN 118−4.009 70.870 5.934 928 CA ASN 118 −4.515 71.924 5.117 929 CB ASN 118−5.792 72.585 5.668 930 CG ASN 118 −6.728 72.663 4.474 931 OD1 ASN 118−7.889 73.063 4.559 932 ND2 ASN 118 −6.183 72.242 3.297 933 C ASN 118−3.456 72.965 4.980 934 O ASN 118 −2.807 73.313 5.965 935 N ASN 119−3.287 73.472 3.737 936 CA ASN 119 −2.389 74.541 3.429 937 CB ASN 119−2.715 75.826 4.228 938 CG ASN 119 −2.726 77.026 3.295 939 OD1 ASN 119−2.356 76.927 2.128 940 ND2 ASN 119 −3.176 78.191 3.829 941 C ASN 119−0.997 74.113 3.768 942 O ASN 119 −0.631 74.004 4.936 943 N SER 120−0.159 73.891 2.741 944 CA SER 120 1.227 73.629 3.003 945 CB SER 1201.825 72.593 2.051 946 OG SER 120 3.225 72.475 2.275 947 C SER 120 1.94874.913 2.774 948 O SER 120 2.777 75.327 3.587 949 N LYS 121 1.577 75.5731.658 950 CA LYS 121 1.900 76.952 1.469 951 CB LYS 121 1.066 77.6300.367 952 CG LYS 121 1.773 78.770 −0.370 953 CD LYS 121 0.868 79.960−0.696 954 CE LYS 121 1.473 81.316 −0.302 955 NZ LYS 121 0.577 82.421−0.734 956 C LYS 121 1.549 77.590 2.769 957 O LYS 121 0.451 77.395 3.272958 N PRO 122 2.514 78.312 3.271 959 CA PRO 122 2.601 78.806 4.614 960CD PRO 122 3.550 78.850 2.416 961 CB PRO 122 3.212 80.190 4.494 962 CGPRO 122 3.927 80.177 3.092 963 C PRO 122 1.331 78.803 5.411 964 O PRO122 0.380 79.494 5.046 965 N VAL 123 1.309 78.079 6.542 966 CA VAL 1231.025 78.686 7.794 967 CB VAL 123 0.918 77.661 8.842 968 CG1 VAL 123−0.536 77.201 8.825 969 CG2 VAL 123 1.926 76.562 8.478 970 C VAL 1232.224 79.525 8.043 971 O VAL 123 3.352 79.047 7.967 972 N GLU 124 2.02080.832 8.307 973 CA GLU 124 3.172 81.669 8.449 974 CB GLU 124 2.86683.178 8.333 975 CG GLU 124 2.144 83.456 7.014 976 CD GLU 124 1.16084.561 7.251 977 OE1 GLU 124 0.895 85.315 6.274 978 OE2 GLU 124 0.65484.665 8.393 979 C GLU 124 3.820 81.344 9.748 980 O GLU 124 3.520 80.32010.369 981 N ASP 125 4.776 82.179 10.166 982 CA ASP 125 5.386 81.82011.393 983 CB ASP 125 6.713 82.547 11.677 984 CG ASP 125 7.789 81.46711.750 985 OD1 ASP 125 8.740 81.622 12.568 986 OD2 ASP 125 7.669 80.45811.019 987 C ASP 125 4.388 82.158 12.437 988 O ASP 125 3.532 83.02712.260 989 N LYS 126 4.462 81.416 13.553 990 CA LYS 126 3.446 81.44314.550 991 CB LYS 126 3.443 82.732 15.392 992 CG LYS 126 2.727 82.60216.746 993 CD LYS 126 2.985 83.784 17.695 994 CE LYS 126 2.001 84.95317.522 995 NZ LYS 126 1.545 85.469 18.836 996 C LYS 126 2.121 81.30113.875 997 O LYS 126 1.168 82.022 14.171 998 N ASP 127 2.020 80.31312.971 999 CA ASP 127 0.746 79.869 12.493 1000 CB ASP 127 0.560 80.10910.992 1001 CG ASP 127 0.011 81.545 10.862 1002 OD1 ASP 127 −0.56382.048 11.870 1003 OD2 ASP 127 0.117 82.170 9.778 1004 C ASP 127 0.66478.416 12.832 1005 O ASP 127 1.359 77.966 13.734 1006 N ALA 128 −0.22377.632 12.194 1007 CA ALA 128 −0.518 76.456 12.959 1008 CB ALA 128−1.633 76.694 13.985 1009 C ALA 128 −1.017 75.351 12.091 1010 O ALA 128−2.223 75.223 11.876 1011 N VAL 129 −0.107 74.471 11.630 1012 CA VAL 129−0.585 73.258 11.035 1013 CB VAL 129 0.487 72.264 10.671 1014 CG1 VAL129 0.137 71.566 9.354 1015 CG2 VAL 129 1.834 72.984 10.601 1016 C VAL129 −1.396 72.547 12.062 1017 O VAL 129 −1.086 72.590 13.251 1018 N ALA130 −2.434 71.831 11.609 1019 CA ALA 130 −2.852 70.689 12.357 1020 CBALA 130 −4.210 70.865 13.051 1021 C ALA 130 −3.004 69.607 11.344 1022 OALA 130 −3.902 69.657 10.500 1023 N PHE 131 −2.098 68.609 11.388 1024 CAPHE 131 −2.210 67.510 10.483 1025 CB PHE 131 −0.927 66.670 10.393 1026CG PHE 131 0.150 67.498 9.785 1027 CD1 PHE 131 −0.096 68.269 8.671 1028CD2 PHE 131 1.413 67.503 10.333 1029 CE1 PHE 131 0.903 69.016 8.104 1030CE2 PHE 131 2.416 68.258 9.772 1031 CZ PHE 131 2.162 69.014 8.660 1032 CPHE 131 −3.290 66.634 11.039 1033 O PHE 131 −3.893 66.975 12.055 1034 NTHR 132 −3.553 65.488 10.379 1035 CA THR 132 −4.426 64.478 10.913 1036CB THR 132 −5.887 64.814 10.857 1037 OG1 THR 132 −6.196 65.869 11.7471038 CG2 THR 132 −6.686 63.559 11.250 1039 C THR 132 −4.286 63.26810.049 1040 O THR 132 −4.485 63.347 8.838 1041 N CYS 133 −3.948 62.11510.665 1042 CA CYS 133 −3.904 60.858 9.966 1043 CB CYS 133 −3.066 59.79910.718 1044 SG CYS 133 −3.858 58.174 10.804 1045 C CYS 133 −5.322 60.3769.928 1046 O CYS 133 −6.132 60.760 10.772 1047 N GLU 134 −5.673 59.5388.927 1048 CA GLU 134 −6.973 58.931 8.968 1049 CB GLU 134 −7.988 59.4077.926 1050 CG GLU 134 −8.135 60.915 7.792 1051 CD GLU 134 −9.074 61.1406.629 1052 OE1 GLU 134 −9.334 62.317 6.282 1053 OE2 GLU 134 −9.55260.116 6.072 1054 C GLU 134 −6.801 57.471 8.701 1055 O GLU 134 −6.00057.037 7.872 1056 N PRO 135 −7.574 56.725 9.423 1057 CA PRO 135 −7.16155.379 9.658 1058 CD PRO 135 −7.949 57.348 10.676 1059 CB PRO 135 −6.51155.397 11.029 1060 CG PRO 135 −7.040 56.679 11.718 1061 C PRO 135 −8.39854.557 9.743 1062 O PRO 135 −9.482 55.108 9.918 1063 N GLU 136 −8.27853.225 9.669 1064 CA GLU 136 −9.500 52.514 9.885 1065 CB GLU 136 −10.29152.250 8.585 1066 CG GLU 136 −11.765 52.668 8.709 1067 CD GLU 136−12.384 53.025 7.348 1068 OE1 GLU 136 −13.604 53.344 7.358 1069 OE2 GLU136 −11.688 52.979 6.298 1070 C GLU 136 −9.201 51.228 10.568 1071 O GLU136 −9.016 50.196 9.921 1072 N THR 137 −9.160 51.265 11.920 1073 CA THR137 −8.949 50.086 12.708 1074 CB THR 137 −7.682 49.395 12.342 1075 OG1THR 137 −7.336 48.461 13.353 1076 CG2 THR 137 −6.608 50.494 12.200 1077C THR 137 −8.798 50.523 14.140 1078 O THR 137 −8.491 51.679 14.433 1079N GLN 138 −9.033 49.590 15.080 1080 CA GLN 138 −8.922 49.938 16.470 1081CB GLN 138 −10.246 49.820 17.258 1082 CG GLN 138 −10.970 48.484 17.0851083 CD GLN 138 −12.367 48.683 17.665 1084 OE1 GLN 138 −12.664 49.80018.079 1085 NE2 GLN 138 −13.209 47.617 17.736 1086 C GLN 138 −7.92049.035 17.111 1087 O GLN 138 −7.519 48.013 16.550 1088 N ASP 139 −7.50049.432 18.327 1089 CA ASP 139 −6.446 48.866 19.120 1090 CB ASP 139−6.452 47.330 19.191 1091 CG ASP 139 −5.896 46.965 20.574 1092 OD1 ASP139 −5.276 45.877 20.685 1093 OD2 ASP 139 −6.063 47.771 21.536 1094 CASP 139 −5.138 49.347 18.586 1095 O ASP 139 −4.139 48.619 18.584 1096 NALA 140 −5.115 50.609 18.123 1097 CA ALA 140 −3.955 51.134 17.472 1098CB ALA 140 −4.276 52.156 16.364 1099 C ALA 140 −3.102 51.851 18.470 1100O ALA 140 −3.370 51.842 19.671 1101 N THR 141 −2.037 52.492 17.953 1102CA THR 141 −1.035 53.172 18.721 1103 CB THR 141 −0.133 52.205 19.4251104 OG1 THR 141 1.118 52.792 19.740 1105 CG2 THR 141 0.065 50.98418.512 1106 C THR 141 −0.231 53.952 17.728 1107 O THR 141 0.731 53.44017.149 1108 N TYR 142 −0.648 55.208 17.494 1109 CA TYR 142 −0.183 56.02216.404 1110 CB TYR 142 −1.165 57.173 16.119 1111 CG TYR 142 −0.71758.109 15.030 1112 CD1 TYR 142 −0.637 57.703 13.712 1113 CD2 TYR 142−0.389 59.415 15.347 1114 CE1 TYR 142 −0.234 58.609 12.760 1115 CE2 TYR142 0.014 60.324 14.396 1116 CZ TYR 142 0.095 59.910 13.086 1117 OH TYR142 0.506 60.799 12.070 1118 C TYR 142 1.117 56.644 16.808 1119 O TYR142 1.378 56.888 17.987 1120 N LEU 143 1.989 56.941 15.823 1121 CA LEU143 3.055 57.837 16.143 1122 CB LEU 143 4.433 57.177 16.360 1123 CG LEU143 4.746 57.012 17.860 1124 CD2 LEU 143 6.259 56.943 18.119 1125 CD1LEU 143 3.969 55.842 18.481 1126 C LEU 143 3.185 58.846 15.039 1127 OLEU 143 2.655 58.664 13.944 1128 N TRP 144 3.879 59.964 15.325 1129 CATRP 144 4.060 61.028 14.371 1130 CB TRP 144 3.721 62.410 14.974 1131 CGTRP 144 2.260 62.807 14.961 1132 CD2 TRP 144 1.584 63.287 13.793 1133CD1 TRP 144 1.327 62.792 15.964 1134 NE1 TRP 144 0.112 63.218 15.4771135 CE2 TRP 144 0.257 63.528 14.143 1136 CE3 TRP 144 2.039 63.50112.518 1137 CZ2 TRP 144 −0.643 63.985 13.223 1138 CZ3 TRP 144 1.13363.979 11.601 1139 CH2 TRP 144 −0.182 64.214 11.942 1140 C TRP 144 5.51761.023 13.996 1141 O TRP 144 6.347 60.580 14.789 1142 N TRP 145 5.88861.501 12.781 1143 CA TRP 145 7.281 61.476 12.393 1144 CB TRP 145 7.67560.261 11.518 1145 CG TRP 145 7.338 58.887 12.069 1146 CD2 TRP 145 7.87558.354 13.288 1147 CD1 TRP 145 6.529 57.918 11.556 1148 NE1 TRP 1456.521 56.815 12.376 1149 CE2 TRP 145 7.345 57.072 13.452 1150 CE3 TRP145 8.733 58.887 14.199 1151 CZ2 TRP 145 7.675 56.309 14.532 1152 CZ3TRP 145 9.063 58.116 15.294 1153 CH2 TRP 145 8.539 56.851 15.457 1154 CTRP 145 7.597 62.682 11.556 1155 O TRP 145 6.693 63.350 11.056 1156 NVAL 146 8.908 62.992 11.385 1157 CA VAL 146 9.323 64.139 10.626 1158 CBVAL 146 9.649 65.359 11.443 1159 CG1 VAL 146 9.919 66.511 10.460 1160CG2 VAL 146 8.519 65.641 12.441 1161 C VAL 146 10.599 63.814 9.914 1162O VAL 146 11.601 63.461 10.535 1163 N ASN 147 10.586 63.959 8.578 1164CA ASN 147 11.746 63.685 7.778 1165 CB ASN 147 12.902 64.687 7.963 1166CG ASN 147 12.796 65.750 6.875 1167 OD1 ASN 147 13.633 66.645 6.769 1168ND2 ASN 147 11.740 65.644 6.030 1169 C ASN 147 12.262 62.334 8.122 1170O ASN 147 13.466 62.085 8.068 1171 N ASN 148 11.343 61.414 8.452 1172 CAASN 148 11.727 60.052 8.619 1173 CB ASN 148 12.484 59.489 7.414 1174 CGASN 148 12.508 57.979 7.548 1175 OD1 ASN 148 13.260 57.304 6.850 1176ND2 ASN 148 11.685 57.433 8.477 1177 C ASN 148 12.646 59.979 9.776 1178O ASN 148 13.570 59.168 9.788 1179 N GLN 149 12.395 60.812 10.804 1180CA GLN 149 12.975 60.475 12.070 1181 CB GLN 149 14.480 60.809 12.2341182 CG GLN 149 15.313 59.535 12.486 1183 CD GLN 149 16.812 59.69112.189 1184 OE1 GLN 149 17.313 60.680 11.664 1185 NE2 GLN 149 17.56058.636 12.584 1186 C GLN 149 12.157 61.090 13.154 1187 O GLN 149 11.01461.479 12.929 1188 N SER 150 12.685 61.119 14.388 1189 CA SER 150 11.73861.139 15.458 1190 CB SER 150 12.320 60.824 16.832 1191 OG SER 15011.271 60.552 17.750 1192 C SER 150 11.164 62.506 15.559 1193 O SER 15011.556 63.399 14.804 1194 N LEU 151 10.186 62.694 16.464 1195 CA LEU 1519.900 64.048 16.751 1196 CB LEU 151 8.535 64.615 16.341 1197 CG LEU 1518.640 66.156 16.461 1198 CD2 LEU 151 7.410 66.880 17.049 1199 CD1 LEU151 9.155 66.740 15.140 1200 C LEU 151 9.788 64.119 18.210 1201 O LEU151 8.660 63.899 18.660 1202 N PRO 152 10.888 64.445 18.911 1203 CA PRO152 10.779 65.395 19.997 1204 CD PRO 152 12.133 64.690 18.191 1205 CBPRO 152 11.364 66.682 19.442 1206 CG PRO 152 12.512 66.136 18.558 1207 CPRO 152 9.419 65.483 20.654 1208 O PRO 152 9.121 64.618 21.481 1209 NVAL 153 8.557 66.441 20.256 1210 CA VAL 153 7.418 66.894 21.019 1211 CBVAL 153 6.960 66.110 22.223 1212 CG1 VAL 153 5.911 66.956 22.969 1213CG2 VAL 153 6.428 64.730 21.824 1214 C VAL 153 7.876 68.155 21.639 1215O VAL 153 8.935 68.195 22.260 1216 N SER 154 7.128 69.245 21.491 1217 CASER 154 7.696 70.378 22.124 1218 CB SER 154 8.600 71.198 21.198 1219 OGSER 154 9.074 70.387 20.139 1220 C SER 154 6.542 71.220 22.520 1221 OSER 154 5.432 70.984 22.036 1222 N PRO 155 6.765 72.150 23.394 1223 CAPRO 155 5.644 72.723 24.066 1224 CD PRO 155 7.921 72.063 24.291 1225 CBPRO 155 6.220 73.559 25.196 1226 CG PRO 155 7.501 72.815 25.573 1227 CPRO 155 4.731 73.462 23.138 1228 O PRO 155 3.722 73.970 23.625 1229 NARG 156 5.016 73.528 21.817 1230 CA ARG 156 4.089 74.154 20.920 1231 CBARG 156 4.751 74.960 19.792 1232 CG ARG 156 6.174 74.492 19.518 1233 CDARG 156 6.810 75.111 18.277 1234 NE ARG 156 7.830 74.139 17.797 1235 CZARG 156 8.375 74.276 16.549 1236 NH1 ARG 156 8.045 75.361 15.791 1237NH2 ARG 156 9.233 73.327 16.065 1238 C ARG 156 3.238 73.119 20.247 1239O ARG 156 2.238 73.481 19.617 1240 N LEU 157 3.580 71.811 20.351 1241 CALEU 157 2.705 70.846 19.730 1242 CB LEU 157 3.411 69.552 19.249 1243 CGLEU 157 4.457 69.808 18.146 1244 CD2 LEU 157 4.706 68.568 17.256 1245CD1 LEU 157 5.754 70.378 18.734 1246 C LEU 157 1.605 70.477 20.676 1247O LEU 157 1.613 70.833 21.857 1248 N GLN 158 0.599 69.774 20.134 1249 CAGLN 158 −0.585 69.475 20.872 1250 CB GLN 158 −1.544 70.689 20.933 1251CG GLN 158 −2.269 70.909 22.270 1252 CD GLN 158 −3.467 71.845 22.0701253 OE1 GLN 158 −4.613 71.452 22.289 1254 NE2 GLN 158 −3.200 73.11721.655 1255 C GLN 158 −1.272 68.426 20.067 1256 O GLN 158 −1.800 68.71118.995 1257 N LEU 159 −1.277 67.166 20.521 1258 CA LEU 159 −2.049 66.26119.727 1259 CB LEU 159 −1.301 65.015 19.214 1260 CG LEU 159 −0.35164.364 20.224 1261 CD2 LEU 159 1.039 65.003 20.199 1262 CD1 LEU 159−0.299 62.854 19.997 1263 C LEU 159 −3.202 65.803 20.553 1264 O LEU 159−3.299 66.088 21.749 1265 N SER 160 −4.149 65.105 19.909 1266 CA SER 160−5.311 64.719 20.646 1267 CB SER 160 −6.337 65.853 20.773 1268 OG SER160 −6.286 66.665 19.610 1269 C SER 160 −5.959 63.628 19.881 1270 O SER160 −5.486 63.242 18.813 1271 N ASN 161 −7.076 63.100 20.404 1272 CA ASN161 −7.843 62.205 19.594 1273 CB ASN 161 −8.216 62.821 18.229 1274 CGASN 161 −9.727 62.933 18.077 1275 OD1 ASN 161 −10.229 62.999 16.954 1276ND2 ASN 161 −10.476 62.955 19.212 1277 C ASN 161 −7.043 60.969 19.3261278 O ASN 161 −7.053 60.458 18.205 1279 N GLY 162 −6.357 60.442 20.3581280 CA GLY 162 −5.710 59.172 20.224 1281 C GLY 162 −4.395 59.386 19.5581282 O GLY 162 −3.627 58.433 19.421 1283 N ASN 163 −4.118 60.641 19.1331284 CA ASN 163 −2.968 61.028 18.344 1285 CB ASN 163 −1.855 59.99418.080 1286 CG ASN 163 −1.029 59.665 19.302 1287 OD1 ASN 163 0.11059.234 19.132 1288 ND2 ASN 163 −1.571 59.843 20.533 1289 C ASN 163−3.440 61.158 16.959 1290 O ASN 163 −2.684 60.879 16.031 1291 N ARG 164−4.705 61.504 16.748 1292 CA ARG 164 −5.079 61.336 15.389 1293 CB ARG164 −6.596 61.254 15.283 1294 CG ARG 164 −7.141 61.085 13.880 1295 CDARG 164 −8.661 61.165 13.915 1296 NE ARG 164 −9.113 61.390 12.535 1297CZ ARG 164 −10.380 61.018 12.188 1298 NH1 ARG 164 −10.801 61.206 10.9071299 NH2 ARG 164 −11.202 60.472 13.126 1300 C ARG 164 −4.579 62.57314.719 1301 O ARG 164 −3.568 62.580 14.019 1302 N THR 165 −5.304 63.66714.994 1303 CA THR 165 −4.976 65.030 14.703 1304 CB THR 165 −6.03165.909 15.270 1305 OG1 THR 165 −6.329 65.444 16.581 1306 CG2 THR 165−7.274 65.844 14.369 1307 C THR 165 −3.732 65.390 15.467 1308 O THR 165−3.537 64.935 16.594 1309 N LEU 166 −2.876 66.242 14.863 1310 CA LEU 166−1.746 66.824 15.541 1311 CB LEU 166 −0.409 66.390 14.907 1312 CG LEU166 0.855 67.085 15.435 1313 CD2 LEU 166 1.914 67.124 14.318 1314 CD1LEU 166 1.349 66.470 16.755 1315 C LEU 166 −1.884 68.305 15.326 1316 OLEU 166 −2.175 68.742 14.213 1317 N THR 167 −1.730 69.133 16.376 1318 CATHR 167 −1.967 70.533 16.157 1319 CB THR 167 −3.245 71.072 16.782 1320OG1 THR 167 −3.441 72.408 16.371 1321 CG2 THR 167 −3.209 70.956 18.3171322 C THR 167 −0.776 71.301 16.655 1323 O THR 167 −0.570 71.478 17.8521324 N LEU 168 0.068 71.764 15.717 1325 CA LEU 168 1.255 72.476 16.0951326 CB LEU 168 2.485 72.191 15.216 1327 CG LEU 168 3.613 73.237 15.3331328 CD2 LEU 168 4.753 72.927 14.350 1329 CD1 LEU 168 4.102 73.43116.786 1330 C LEU 168 0.973 73.927 15.955 1331 O LEU 168 0.405 74.38314.960 1332 N PHE 169 1.387 74.697 16.979 1333 CA PHE 169 1.237 76.10816.890 1334 CB PHE 169 −0.211 76.515 16.574 1335 CG PHE 169 −0.62677.786 17.222 1336 CD1 PHE 169 0.069 78.961 17.075 1337 CD2 PHE 169−1.766 77.774 17.993 1338 CE1 PHE 169 −0.357 80.111 17.702 1339 CE2 PHE169 −2.201 78.916 18.622 1340 CZ PHE 169 −1.498 80.082 18.478 1341 C PHE169 1.675 76.644 18.207 1342 O PHE 169 1.176 76.259 19.265 1343 N ASN170 2.677 77.535 18.154 1344 CA ASN 170 3.002 78.149 16.905 1345 CB ASN170 3.641 79.543 17.058 1346 CG ASN 170 4.567 79.460 18.253 1347 OD1 ASN170 4.244 79.994 19.315 1348 ND2 ASN 170 5.720 78.755 18.099 1349 C ASN170 4.007 77.300 16.198 1350 O ASN 170 4.511 76.304 16.718 1351 N VAL171 4.318 77.686 14.957 1352 CA VAL 171 5.109 76.877 14.098 1353 CB VAL171 4.280 76.359 12.933 1354 CG1 VAL 171 3.884 77.547 12.035 1355 CG2VAL 171 5.002 75.200 12.220 1356 C VAL 171 6.184 77.802 13.617 1357 OVAL 171 6.036 79.013 13.738 1358 N THR 172 7.309 77.292 13.094 1359 CATHR 172 8.309 78.234 12.711 1360 CB THR 172 9.403 78.422 13.740 1361 OG1THR 172 10.212 79.535 13.402 1362 CG2 THR 172 10.261 77.142 13.877 1363C THR 172 8.890 77.797 11.395 1364 O THR 172 8.171 77.290 10.535 1365 NARG 173 10.205 77.999 11.200 1366 CA ARG 173 10.874 77.547 10.015 1367CB ARG 173 12.027 78.468 9.639 1368 CG ARG 173 13.007 78.691 10.791 1369CD ARG 173 13.982 79.796 10.412 1370 NE ARG 173 14.983 80.022 11.4961371 CZ ARG 173 16.214 80.477 11.135 1372 NH1 ARG 173 16.557 80.4969.811 1373 NH2 ARG 173 17.086 80.957 12.072 1374 C ARG 173 11.479 76.20310.288 1375 O ARG 173 12.012 75.552 9.390 1376 N ASN 174 11.444 75.73311.543 1377 CA ASN 174 12.118 74.486 11.748 1378 CB ASN 174 12.30674.112 13.228 1379 CG ASN 174 13.654 73.391 13.350 1380 OD1 ASN 17413.942 72.747 14.356 1381 ND2 ASN 174 14.511 73.542 12.308 1382 C ASN174 11.278 73.430 11.107 1383 O ASN 174 11.779 72.391 10.685 1384 N ASP175 9.957 73.684 11.019 1385 CA ASP 175 9.030 72.666 10.622 1386 CB ASP175 7.630 72.841 11.248 1387 CG ASP 175 7.817 72.957 12.755 1388 OD1 ASP175 7.175 73.835 13.390 1389 OD2 ASP 175 8.628 72.159 13.295 1390 C ASP175 8.880 72.708 9.130 1391 O ASP 175 7.767 72.647 8.612 1392 N THR 17610.012 72.774 8.398 1393 CA THR 176 9.955 72.501 6.991 1394 CB THR 17610.818 73.403 6.156 1395 OG1 THR 176 11.144 72.761 4.940 1396 CG2 THR176 12.097 73.728 6.948 1397 C THR 176 10.465 71.111 6.792 1398 O THR176 11.669 70.869 6.779 1399 N ALA 177 9.535 70.154 6.619 1400 CA ALA177 9.889 68.805 6.298 1401 CB ALA 177 10.546 68.041 7.460 1402 C ALA177 8.616 68.103 5.995 1403 O ALA 177 7.546 68.522 6.432 1404 N SER 1788.690 67.011 5.213 1405 CA SER 178 7.520 66.219 5.019 1406 CB SER 1787.707 65.075 4.005 1407 OG SER 178 6.537 64.274 3.933 1408 C SER 1787.245 65.616 6.344 1409 O SER 178 8.132 65.022 6.951 1410 N TYR 1796.013 65.762 6.855 1411 CA TYR 179 5.740 65.085 8.085 1412 CB TYR 1794.984 65.943 9.123 1413 CG TYR 179 5.927 66.937 9.729 1414 CD1 TYR 1796.036 67.041 11.100 1415 CD2 TYR 179 6.680 67.769 8.935 1416 CE1 TYR 1796.896 67.958 11.665 1417 CE2 TYR 179 7.540 68.684 9.499 1418 CZ TYR 1797.642 68.784 10.864 1419 OH TYR 179 8.526 69.736 11.418 1420 C TYR 1794.921 63.875 7.733 1421 O TYR 179 3.903 63.975 7.049 1422 N LYS 1805.386 62.685 8.163 1423 CA LYS 180 4.812 61.451 7.704 1424 CB LYS 1805.861 60.329 7.580 1425 CG LYS 180 5.738 59.384 6.376 1426 CD LYS 1807.076 58.709 6.047 1427 CE LYS 180 7.005 57.517 5.094 1428 NZ LYS 1808.379 56.995 4.915 1429 C LYS 180 3.820 61.021 8.735 1430 O LYS 1803.618 61.689 9.754 1431 N CYS 181 3.162 59.870 8.507 1432 CA CYS 1812.346 59.308 9.536 1433 CB CYS 181 0.843 59.360 9.197 1434 SG CYS 181−0.043 57.809 9.575 1435 C CYS 181 2.720 57.866 9.654 1436 O CYS 1812.945 57.203 8.644 1437 N GLU 182 2.790 57.336 10.886 1438 CA GLU 1822.891 55.912 10.975 1439 CB GLU 182 4.308 55.377 11.229 1440 CG GLU 1824.386 53.907 10.858 1441 CD GLU 182 5.659 53.237 11.331 1442 OE1 GLU 1826.334 53.721 12.284 1443 OE2 GLU 182 5.955 52.176 10.731 1444 C GLU 1822.051 55.444 12.124 1445 O GLU 182 1.864 56.156 13.114 1446 N THR 1831.525 54.208 12.002 1447 CA THR 183 0.887 53.575 13.108 1448 CB THR 183−0.512 53.168 12.820 1449 OG1 THR 183 −0.899 53.744 11.586 1450 CG2 THR183 −1.421 53.660 13.956 1451 C THR 183 1.661 52.335 13.345 1452 O THR183 2.630 52.053 12.643 1453 N GLN 184 1.269 51.552 14.357 1454 CA GLN184 2.038 50.381 14.624 1455 CB GLN 184 3.094 50.616 15.730 1456 CG GLN184 4.189 49.546 15.762 1457 CD GLN 184 5.296 49.994 16.718 1458 OE1 GLN184 6.125 49.192 17.148 1459 NE2 GLN 184 5.281 51.299 17.093 1460 C GLN184 1.081 49.339 15.093 1461 O GLN 184 −0.125 49.446 14.883 1462 N ASN185 1.617 48.316 15.774 1463 CA ASN 185 0.859 47.438 16.613 1464 CB ASN185 −0.430 46.880 15.937 1465 CG ASN 185 −0.206 45.640 15.083 1466 OD1ASN 185 −0.609 44.539 15.453 1467 ND2 ASN 185 0.414 45.820 13.887 1468 CASN 185 1.832 46.378 17.005 1469 O ASN 185 3.002 46.550 16.662 1470 NPRO 186 1.482 45.322 17.704 1471 CA PRO 186 2.358 44.196 17.833 1472 CDPRO 186 0.170 45.092 18.285 1473 CB PRO 186 1.584 43.101 18.553 1474 CGPRO 186 0.307 43.779 19.075 1475 C PRO 186 2.700 43.847 16.431 1476 OPRO 186 1.782 43.516 15.680 1477 N VAL 187 3.993 43.984 16.080 1478 CAVAL 187 4.389 44.547 14.820 1479 CB VAL 187 5.820 44.304 14.443 1480 CG1VAL 187 6.032 44.826 13.013 1481 CG2 VAL 187 6.738 44.955 15.493 1482 CVAL 187 3.590 43.981 13.707 1483 O VAL 187 3.662 42.784 13.432 1484 NSER 188 2.854 44.861 13.003 1485 CA SER 188 2.614 44.657 11.609 1486 CBSER 188 1.493 43.646 11.299 1487 OG SER 188 0.618 43.512 12.408 1488 CSER 188 2.237 45.999 11.068 1489 O SER 188 1.062 46.296 10.844 1490 NALA 189 3.261 46.861 10.886 1491 CA ALA 189 3.070 48.267 10.707 1492 CBALA 189 4.239 49.094 11.276 1493 C ALA 189 2.968 48.617 9.242 1494 O ALA189 3.192 47.786 8.363 1495 N ARG 190 2.629 49.901 8.979 1496 CA ARG 1902.654 50.555 7.691 1497 CB ARG 190 1.307 50.543 6.946 1498 CG ARG 1900.764 49.157 6.638 1499 CD ARG 190 −0.450 49.154 5.718 1500 NE ARG 190−0.380 47.838 5.045 1501 CZ ARG 190 −0.874 47.651 3.777 1502 NH1 ARG 190−1.628 48.628 3.192 1503 NH2 ARG 190 −0.585 46.493 3.130 1504 C ARG 1902.900 51.997 7.990 1505 O ARG 190 2.899 52.382 9.163 1506 N ARG 1913.091 52.845 6.954 1507 CA ARG 191 3.151 54.272 7.164 1508 CB ARG 1914.536 54.895 6.907 1509 CG ARG 191 5.613 54.501 7.923 1510 CD ARG 1916.942 54.141 7.260 1511 NE ARG 191 7.996 54.055 8.316 1512 CZ ARG 1919.300 54.007 7.938 1513 NH1 ARG 191 9.662 54.003 6.626 1514 NH2 ARG 19110.277 53.961 8.906 1515 C ARG 191 2.177 54.925 6.211 1516 O ARG 1911.373 54.234 5.591 1517 N SER 192 2.206 56.275 6.101 1518 CA SER 1921.243 56.968 5.281 1519 CB SER 192 0.481 58.085 6.033 1520 OG SER 1921.388 59.092 6.454 1521 C SER 192 1.947 57.592 4.117 1522 O SER 1922.862 57.004 3.543 1523 N ASP 193 1.517 58.808 3.710 1524 CA ASP 1932.090 59.451 2.560 1525 CB ASP 193 1.228 60.566 1.959 1526 CG ASP 193−0.220 60.249 2.277 1527 OD1 ASP 193 −0.821 59.463 1.500 1528 OD2 ASP193 −0.750 60.772 3.292 1529 C ASP 193 3.352 60.126 2.973 1530 O ASP 1934.069 59.694 3.872 1531 N SER 194 3.627 61.239 2.275 1532 CA SER 1944.675 62.121 2.671 1533 CB SER 194 6.048 61.728 2.090 1534 OG SER 1946.246 60.340 2.303 1535 C SER 194 4.292 63.471 2.152 1536 O SER 1944.550 63.807 0.995 1537 N VAL 195 3.638 64.265 3.020 1538 CA VAL 1953.203 65.589 2.681 1539 CB VAL 195 2.030 66.040 3.500 1540 CG1 VAL 1950.850 65.112 3.192 1541 CG2 VAL 195 2.412 65.993 4.989 1542 C VAL 1954.329 66.517 2.974 1543 O VAL 195 4.919 66.494 4.050 1544 N ILE 1964.706 67.372 2.015 1545 CA ILE 196 5.829 68.180 2.373 1546 CB ILE 1966.885 68.313 1.318 1547 CG2 ILE 196 6.217 68.752 0.006 1548 CG1 ILE 1967.986 69.267 1.811 1549 CD1 ILE 196 8.954 69.688 0.720 1550 C ILE 1965.327 69.538 2.732 1551 O ILE 196 4.324 70.020 2.202 1552 N LEU 1975.996 70.185 3.703 1553 CA LEU 197 5.411 71.396 4.185 1554 CB LEU 1974.822 71.286 5.590 1555 CG LEU 197 3.701 72.319 5.823 1556 CD2 LEU 1973.522 72.601 7.319 1557 CD1 LEU 197 2.398 71.924 5.121 1558 C LEU 1976.450 72.451 4.247 1559 O LEU 197 7.301 72.459 5.137 1560 N ASN 1986.371 73.407 3.307 1561 CA ASN 198 7.287 74.493 3.373 1562 CB ASN 1987.899 74.895 2.041 1563 CG ASN 198 8.708 73.708 1.548 1564 OD1 ASN 1989.294 72.985 2.355 1565 ND2 ASN 198 8.757 73.503 0.207 1566 C ASN 1986.525 75.677 3.826 1567 O ASN 198 5.534 76.070 3.212 1568 N VAL 1997.013 76.294 4.915 1569 CA VAL 199 6.481 77.537 5.368 1570 CB VAL 1996.835 77.844 6.787 1571 CG1 VAL 199 8.363 77.994 6.868 1572 CG2 VAL 1996.014 79.070 7.250 1573 C VAL 199 7.134 78.588 4.536 1574 O VAL 1998.232 78.393 4.017 1575 N LEU 200 6.457 79.751 4.424 1576 CA LEU 2007.033 80.994 4.007 1577 CB LEU 200 6.575 81.548 2.649 1578 CG LEU 2006.797 83.077 2.543 1579 CD2 LEU 200 6.213 83.641 1.239 1580 CD1 LEU 2008.271 83.436 2.734 1581 C LEU 200 6.494 81.964 4.974 1582 O LEU 2005.281 82.109 5.127 1583 N TYR 201 7.412 82.649 5.661 1584 CA TYR 2017.063 83.577 6.676 1585 CB TYR 201 8.309 84.123 7.409 1586 CG TYR 2019.522 83.684 6.626 1587 CD1 TYR 201 10.072 84.480 5.643 1588 CD2 TYR 20110.119 82.459 6.860 1589 CE1 TYR 201 11.174 84.083 4.923 1590 CE2 TYR201 11.228 82.059 6.138 1591 CZ TYR 201 11.771 82.864 5.160 1592 OH TYR201 12.905 82.456 4.421 1593 C TYR 201 6.423 84.694 5.955 1594 O TYR 2016.317 84.674 4.730 1595 N GLY 202 5.999 85.721 6.716 1596 CA GLY 2025.666 87.004 6.174 1597 C GLY 202 6.259 87.999 7.119 1598 O GLY 2025.629 88.401 8.101 1599 N PRO 203 7.486 88.391 6.839 1600 CA PRO 2038.295 89.066 7.826 1601 CD PRO 203 8.254 87.749 5.805 1602 CB PRO 2039.754 88.849 7.427 1603 CG PRO 203 9.719 87.815 6.297 1604 C PRO 2037.997 90.541 7.906 1605 O PRO 203 7.018 91.043 7.304 1606 OXT PRO 2038.804 91.221 8.590

[0138] TABLE 4 Full coordinate set of domains N and A1 of human CEACAM1(homology model)(1587 atoms, 203 amino acids) ANum AType RType RNum X YZ 1 N GLN 1 7.745 28.820 40.481 2 CA GLN 1 7.968 27.374 40.321 3 CB GLN1 6.951 26.588 41.158 4 CG GLN 1 6.002 27.513 41.923 5 CD GLN 1 4.80526.718 42.405 6 OE1 GLN 1 4.676 25.534 42.096 7 NE2 GLN 1 3.900 27.38643.176 8 C GLN 1 7.803 26.950 38.910 9 O GLN 1 6.852 26.235 38.607 10 NLEU 2 8.763 27.375 38.060 11 CA LEU 2 9.146 26.719 36.849 12 CB LEU 210.105 25.557 37.169 13 CG LEU 2 10.544 24.703 35.971 14 CD2 LEU 210.819 23.253 36.406 15 CD1 LEU 2 11.709 25.366 35.222 16 C LEU 2 7.94826.174 36.134 17 O LEU 2 7.665 24.983 36.228 18 N THR 3 7.204 27.00935.390 19 CA THR 3 6.354 26.364 34.436 20 CB THR 3 4.901 26.252 34.79021 OG1 THR 3 4.380 27.522 35.127 22 CG2 THR 3 4.750 25.257 35.938 23 CTHR 3 6.358 27.122 33.173 24 O THR 3 7.377 27.626 32.695 25 N THR 45.151 27.150 32.592 26 CA THR 4 4.942 27.242 31.185 27 CB THR 4 3.47427.108 30.845 28 OG1 THR 4 3.248 26.953 29.453 29 CG2 THR 4 2.752 28.35531.384 30 C THR 4 5.417 28.566 30.701 31 O THR 4 6.008 29.370 31.421 32N GLU 5 5.159 28.791 29.416 33 CA GLU 5 5.330 30.049 28.792 34 CB GLU 56.781 30.215 28.258 35 CG GLU 5 7.079 31.549 27.586 36 CD GLU 5 7.45731.212 26.156 37 OE1 GLU 5 7.953 30.071 25.963 38 OE2 GLU 5 7.281 32.06225.244 39 C GLU 5 4.342 29.985 27.675 40 O GLU 5 3.367 29.235 27.737 41N SER 6 4.554 30.766 26.613 42 CA SER 6 3.800 30.517 25.431 43 CB SER 62.280 30.724 25.559 44 OG SER 6 1.673 30.516 24.293 45 C SER 6 4.30931.460 24.422 46 O SER 6 4.771 32.549 24.740 47 N MET 7 4.266 31.03123.159 48 CA MET 7 4.925 31.763 22.128 49 CB MET 7 6.394 31.288 21.99750 CG MET 7 7.179 31.842 20.810 51 SD MET 7 8.328 30.663 20.038 52 CEMET 7 7.852 31.081 18.336 53 C MET 7 4.186 31.445 20.866 54 O MET 73.557 30.396 20.762 55 N PRO 8 4.224 32.278 19.875 56 CA PRO 8 4.90933.534 19.906 57 CD PRO 8 3.959 31.792 18.536 58 CB PRO 8 5.135 33.92918.443 59 CG PRO 8 4.824 32.660 17.621 60 C PRO 8 4.066 34.517 20.649 61O PRO 8 2.882 34.616 20.340 62 N PHE 9 4.627 35.266 21.617 63 CA PHE 93.779 36.245 22.231 64 CB PHE 9 4.411 37.010 23.396 65 CG PHE 9 5.86136.691 23.383 66 CD1 PHE 9 6.754 37.498 22.713 67 CD2 PHE 9 6.308 35.56824.038 68 CE1 PHE 9 8.092 37.189 22.695 69 CE2 PHE 9 7.645 35.256 24.02370 CZ PHE 9 8.531 36.067 23.357 71 C PHE 9 3.440 37.247 21.200 72 O PHE9 4.258 37.576 20.350 73 N ASN 10 2.201 37.752 21.257 74 CA ASN 10 1.68938.607 20.248 75 CB ASN 10 2.618 39.784 19.929 76 CG ASN 10 2.576 40.66821.168 77 OD1 ASN 10 3.558 40.865 21.880 78 ND2 ASN 10 1.353 41.17421.467 79 C ASN 10 1.437 37.766 19.052 80 O ASN 10 2.340 37.151 18.48481 N VAL 11 0.154 37.692 18.674 82 CA VAL 11 −0.247 36.736 17.695 83 CBVAL 11 −1.092 35.654 18.293 84 CG1 VAL 11 −0.845 34.359 17.507 85 CG2VAL 11 −0.740 35.562 19.789 86 C VAL 11 −1.059 37.471 16.691 87 O VAL 11−1.804 38.385 17.038 88 N ALA 12 −0.934 37.089 15.410 89 CA ALA 12−1.721 37.744 14.412 90 CB ALA 12 −0.983 37.913 13.081 91 C ALA 12−2.911 36.891 14.144 92 O ALA 12 −3.074 35.821 14.719 93 N GLU 13 −3.78337.365 13.240 94 CA GLU 13 −4.919 36.592 12.861 95 CB GLU 13 −6.04137.476 12.310 96 CG GLU 13 −7.395 37.293 12.980 97 CD GLU 13 −8.40437.892 12.028 98 OE1 GLU 13 −9.298 38.637 12.512 99 OE2 GLU 13 −8.28037.613 10.807 100 C GLU 13 −4.472 35.715 11.735 101 O GLU 13 −3.65736.118 10.910 102 N GLY 14 −5.001 34.480 11.664 103 CA GLY 14 −4.63733.601 10.588 104 C GLY 14 −3.273 33.050 10.873 105 O GLY 14 −2.67432.367 10.041 106 N LYS 15 −2.729 33.326 12.071 107 CA LYS 15 −1.45332.742 12.349 108 CB LYS 15 −0.341 33.782 12.545 109 CG LYS 15 −0.30034.740 11.349 110 CD LYS 15 0.971 35.585 11.223 111 CE LYS 15 1.89235.139 10.088 112 NZ LYS 15 2.889 34.192 10.624 113 C LYS 15 −1.60431.914 13.582 114 O LYS 15 −2.562 32.062 14.337 115 N GLU 16 −0.65430.980 13.784 116 CA GLU 16 −0.793 30.008 14.822 117 CB GLU 16 −0.09928.662 14.531 118 CG GLU 16 −0.817 27.763 13.526 119 CD GLU 16 0.06626.548 13.284 120 OE1 GLU 16 −0.479 25.412 13.252 121 OE2 GLU 16 1.30126.743 13.127 122 C GLU 16 −0.138 30.521 16.060 123 O GLU 16 0.36931.639 16.111 124 N VAL 17 −0.165 29.654 17.091 125 CA VAL 17 0.38529.886 18.395 126 CB VAL 17 −0.627 30.335 19.401 127 CG1 VAL 17 0.08630.552 20.744 128 CG2 VAL 17 −1.377 31.568 18.873 129 C VAL 17 0.78528.550 18.887 130 O VAL 17 0.121 27.557 18.600 131 N LEU 18 1.871 28.47119.673 132 CA LEU 18 2.081 27.227 20.340 133 CB LEU 18 3.385 26.48819.986 134 CG LEU 18 3.803 25.486 21.084 135 CD2 LEU 18 5.288 25.10520.958 136 CD1 LEU 18 2.878 24.262 21.138 137 C LEU 18 2.153 27.52021.793 138 O LEU 18 2.692 28.539 22.220 139 N LEU 19 1.596 26.619 22.605140 CA LEU 19 1.671 26.891 23.998 141 CB LEU 19 0.357 26.603 24.728 142CG LEU 19 −0.699 27.719 24.495 143 CD2 LEU 19 −0.657 28.261 23.052 144CD1 LEU 19 −0.582 28.810 25.568 145 C LEU 19 2.768 26.048 24.537 146 OLEU 19 2.767 24.831 24.360 147 N LEU 20 3.770 26.686 25.171 148 CA LEU20 4.972 25.975 25.479 149 CB LEU 20 6.241 26.789 25.167 150 CG LEU 207.476 25.958 24.757 151 CD2 LEU 20 8.768 26.791 24.823 152 CD1 LEU 207.290 25.316 23.372 153 C LEU 20 4.984 25.709 26.937 154 O LEU 20 5.15226.632 27.732 155 N VAL 21 4.848 24.432 27.335 156 CA VAL 21 5.19924.150 28.687 157 CB VAL 21 4.536 22.938 29.273 158 CG1 VAL 21 5.37922.415 30.449 159 CG2 VAL 21 3.106 23.324 29.691 160 C VAL 21 6.65423.881 28.641 161 O VAL 21 7.147 23.341 27.657 162 N HIS 22 7.382 24.27329.699 163 CA HIS 22 8.770 23.956 29.741 164 ND1 HIS 22 9.278 26.54028.412 165 CG HIS 22 9.501 26.347 29.754 166 CB HIS 22 9.630 25.01930.409 167 NE2 HIS 22 9.414 28.561 29.341 168 CD2 HIS 22 9.576 27.59130.309 169 CE1 HIS 22 9.236 27.889 28.222 170 C HIS 22 8.888 22.75630.586 171 O HIS 22 8.326 21.706 30.287 172 N ASN 23 9.642 22.896 31.686173 CA ASN 23 9.947 21.761 32.494 174 CB ASN 23 11.138 22.009 33.420 175CG ASN 23 12.294 22.403 32.521 176 OD1 ASN 23 12.300 23.480 31.930 177ND2 ASN 23 13.299 21.498 32.399 178 C ASN 23 8.768 21.449 33.346 179 OASN 23 8.108 22.340 33.878 180 N LEU 24 8.504 20.143 33.510 181 CA LEU24 7.454 19.653 34.345 182 CB LEU 24 7.252 20.402 35.675 183 CG LEU 248.495 20.495 36.592 184 CD2 LEU 24 9.388 19.246 36.536 185 CD1 LEU 248.058 20.846 38.025 186 C LEU 24 6.177 19.674 33.588 187 O LEU 24 5.82520.723 33.051 188 N PRO 25 5.430 18.604 33.464 189 CA PRO 25 5.90517.250 33.603 190 CD PRO 25 4.693 18.659 32.217 191 CB PRO 25 6.47216.966 32.217 192 CG PRO 25 5.424 17.652 31.294 193 C PRO 25 6.62116.654 34.793 194 O PRO 25 7.492 17.227 35.441 195 N GLN 26 6.263 15.41035.123 196 CA GLN 26 7.054 14.783 36.126 197 CB GLN 26 6.938 15.44537.517 198 CG GLN 26 8.258 15.403 38.292 199 CD GLN 26 8.203 16.28539.543 200 OE1 GLN 26 8.652 15.808 40.583 201 NE2 GLN 26 7.710 17.55239.470 202 C GLN 26 6.598 13.373 36.215 203 O GLN 26 6.664 12.758 37.278204 N GLN 27 6.152 12.816 35.073 205 CA GLN 27 5.761 11.442 35.082 206CB GLN 27 6.881 10.549 35.638 207 CG GLN 27 6.712 9.051 35.410 208 CDGLN 27 7.531 8.423 36.523 209 OE1 GLN 27 7.878 7.245 36.514 210 NE2 GLN27 7.882 9.284 37.512 211 C GLN 27 4.536 11.402 35.940 212 O GLN 274.488 10.806 37.017 213 N LEU 28 3.513 12.116 35.441 214 CA LEU 28 2.25812.361 36.082 215 CB LEU 28 1.780 13.783 35.787 216 CG LEU 28 3.01014.651 35.434 217 CD2 LEU 28 3.853 14.914 36.689 218 CD1 LEU 28 2.66915.931 34.666 219 C LEU 28 1.279 11.381 35.528 220 O LEU 28 1.554 10.18235.482 221 N PHE 29 0.089 11.848 35.107 222 CA PHE 29 −0.888 10.85134.786 223 CB PHE 29 −1.817 10.508 35.964 224 CG PHE 29 −2.827 9.51935.499 225 CD1 PHE 29 −2.607 8.168 35.639 226 CD2 PHE 29 −4.020 9.91634.928 227 CE1 PHE 29 −3.534 7.242 35.217 228 CE2 PHE 29 −4.946 8.98734.504 229 CZ PHE 29 −4.717 7.645 34.649 230 C PHE 29 −1.768 11.35733.690 231 O PHE 29 −2.107 10.630 32.759 232 N GLY 30 −2.217 12.61433.797 233 CA GLY 30 −3.261 13.008 32.917 234 C GLY 30 −3.193 14.48032.846 235 O GLY 30 −3.083 15.190 33.842 236 N TYR 31 −3.232 15.01231.629 237 CA TYR 31 −3.165 16.433 31.560 238 CB TYR 31 −1.923 17.10330.894 239 CG TYR 31 −0.856 16.224 30.281 240 CD1 TYR 31 0.293 16.85429.862 241 CD2 TYR 31 −0.926 14.855 30.081 242 CE1 TYR 31 1.325 16.14729.287 243 CE2 TYR 31 0.090 14.140 29.516 244 CZ TYR 31 1.219 14.78529.115 245 OH TYR 31 2.261 14.053 28.525 246 C TYR 31 −4.372 16.87330.829 247 O TYR 31 −4.996 16.106 30.102 248 N SER 32 −4.763 18.13331.026 249 CA SER 32 −5.893 18.618 30.311 250 CB SER 32 −7.202 18.46631.111 251 OG SER 32 −8.331 18.854 30.345 252 C SER 32 −5.632 20.06730.086 253 O SER 32 −5.185 20.781 30.984 254 N TRP 33 −5.885 20.53228.852 255 CA TRP 33 −5.791 21.935 28.642 256 CB TRP 33 −5.241 22.33927.268 257 CG TRP 33 −3.741 22.523 27.269 258 CD2 TRP 33 −3.062 23.68527.791 259 CD1 TRP 33 −2.774 21.671 26.830 260 NE1 TRP 33 −1.529 22.20327.077 261 CE2 TRP 33 −1.694 23.441 27.659 262 CE3 TRP 33 −3.538 24.84828.336 263 CZ2 TRP 33 −0.772 24.359 28.087 264 CZ3 TRP 33 −2.602 25.77428.754 265 CH2 TRP 33 −1.248 25.531 28.632 266 C TRP 33 −7.149 22.50028.762 267 O TRP 33 −8.146 21.875 28.396 268 N TYR 34 −7.216 23.72229.302 269 CA TYR 34 −8.503 24.278 29.528 270 CB TYR 34 −8.780 24.47031.020 271 CG TYR 34 −9.040 23.109 31.570 272 CD1 TYR 34 −8.633 22.76332.839 273 CD2 TYR 34 −9.706 22.184 30.794 274 CE1 TYR 34 −8.891 21.50533.340 275 CE2 TYR 34 −9.967 20.932 31.284 276 CZ TYR 34 −9.562 20.58932.554 277 OH TYR 34 −9.839 19.295 33.044 278 C TYR 34 −8.561 25.59028.829 279 O TYR 34 −7.981 25.773 27.759 280 N LYS 35 −9.317 26.53429.416 281 CA LYS 35 −9.519 27.763 28.727 282 CB LYS 35 −10.371 27.60227.454 283 CG LYS 35 −10.539 28.909 26.676 284 CD LYS 35 −11.440 28.78725.445 285 CE LYS 35 −11.134 29.852 24.396 286 NZ LYS 35 −12.108 29.76823.286 287 C LYS 35 −10.272 28.664 29.640 288 O LYS 35 −11.471 28.50329.854 289 N GLY 36 −9.586 29.673 30.190 290 CA GLY 36 −10.333 30.73330.788 291 C GLY 36 −10.512 30.450 32.233 292 O GLY 36 −11.530 30.82032.811 293 N GLU 37 −9.498 29.830 32.865 294 CA GLU 37 −9.402 29.84834.292 295 CB GLU 37 −9.803 31.194 34.905 296 CG GLU 37 −9.569 31.23536.412 297 CD GLU 37 −9.867 32.637 36.903 298 OE1 GLU 37 −9.509 32.95238.069 299 OE2 GLU 37 −10.465 33.408 36.106 300 C GLU 37 −10.295 28.81234.876 301 O GLU 37 −9.905 28.124 35.821 302 N ARG 38 −11.517 28.70534.341 303 CA ARG 38 −12.503 27.833 34.883 304 CB ARG 38 −13.774 27.77134.027 305 CG ARG 38 −14.960 27.211 34.811 306 CD ARG 38 −16.255 27.13834.006 307 NE ARG 38 −17.321 27.741 34.863 308 CZ ARG 38 −18.608 27.32834.745 309 NH1 ARG 38 −19.561 27.764 35.626 310 NH2 ARG 38 −18.95326.457 33.760 311 C ARG 38 −11.889 26.488 34.908 312 O ARG 38 −11.31426.026 33.925 313 N VAL 39 −11.941 25.845 36.075 314 CA VAL 39 −11.12724.692 36.224 315 CB VAL 39 −10.681 24.558 37.642 316 CG1 VAL 39 −9.93323.235 37.818 317 CG2 VAL 39 −9.822 25.793 37.966 318 C VAL 39 −11.96223.526 35.794 319 O VAL 39 −11.494 22.389 35.702 320 N ASP 40 −13.24823.818 35.486 321 CA ASP 40 −14.144 22.841 34.937 322 CB ASP 40 −15.53123.423 34.546 323 CG ASP 40 −16.689 22.750 35.284 324 OD1 ASP 40 −17.85123.117 34.954 325 OD2 ASP 40 −16.440 21.882 36.165 326 C ASP 40 −13.55622.348 33.656 327 O ASP 40 −12.579 22.882 33.130 328 N GLY 41 −14.19321.296 33.118 329 CA GLY 41 −14.005 20.893 31.756 330 C GLY 41 −15.37920.862 31.156 331 O GLY 41 −15.678 20.034 30.291 332 N ASN 42 −16.23721.794 31.628 333 CA ASN 42 −17.506 22.135 31.037 334 CB ASN 42 −17.86123.591 31.403 335 CG ASN 42 −19.327 23.892 31.153 336 OD1 ASN 42 −19.71724.366 30.085 337 ND2 ASN 42 −20.165 23.645 32.190 338 C ASN 42 −17.23322.109 29.577 339 O ASN 42 −17.913 21.452 28.787 340 N ARG 43 −16.14022.809 29.243 341 CA ARG 43 −15.380 22.564 28.070 342 CB ARG 43 −15.02123.859 27.323 343 CG ARG 43 −16.237 24.524 26.690 344 CD ARG 43 −17.05623.501 25.915 345 NE ARG 43 −18.490 23.736 26.208 346 CZ ARG 43 −19.27124.314 25.245 347 NH1 ARG 43 −20.623 24.307 25.374 348 NH2 ARG 43−18.676 24.871 24.149 349 C ARG 43 −14.097 21.978 28.558 350 O ARG 43−13.395 22.591 29.364 351 N GLN 44 −13.759 20.764 28.081 352 CA GLN 44−12.443 20.260 28.326 353 CB GLN 44 −12.412 18.912 29.067 354 CG GLN 44−10.989 18.427 29.356 355 CD GLN 44 −11.059 17.023 29.951 356 OE1 GLN 44−11.444 16.814 31.098 357 NE2 GLN 44 −10.661 16.032 29.122 358 C GLN 44−11.848 20.037 26.984 359 O GLN 44 −12.378 19.277 26.171 360 N ILE 45−10.735 20.729 26.705 361 CA ILE 45 −10.185 20.632 25.394 362 CB ILE 45−9.291 21.799 25.072 363 CG2 ILE 45 −9.572 22.220 23.620 364 CG1 ILE 45−9.552 22.949 26.068 365 CD1 ILE 45 −10.590 23.962 25.577 366 C ILE 45−9.421 19.336 25.323 367 O ILE 45 −9.943 18.344 24.819 368 N VAL 46−8.168 19.307 25.828 369 CA VAL 46 −7.305 18.199 25.510 370 CB VAL 46−5.991 18.634 24.941 371 CG1 VAL 46 −5.196 17.427 24.414 372 CG2 VAL 46−6.305 19.661 23.849 373 C VAL 46 −6.992 17.420 26.747 374 O VAL 46−7.147 17.900 27.870 375 N GLY 47 −6.514 16.171 26.551 376 CA GLY 47−6.037 15.364 27.630 377 C GLY 47 −5.116 14.326 27.061 378 O GLY 47−5.461 13.149 26.966 379 N TYR 48 −3.885 14.723 26.696 380 CA TYR 48−2.951 13.687 26.389 381 CB TYR 48 −1.575 14.189 25.910 382 CG TYR 48−0.653 13.031 25.691 383 CD1 TYR 48 0.316 12.736 26.620 384 CD2 TYR 48−0.718 12.246 24.560 385 CE1 TYR 48 1.184 11.683 26.437 386 CE2 TYR 480.150 11.189 24.371 387 CZ TYR 48 1.105 10.896 25.310 388 OH TYR 481.996 9.816 25.123 389 C TYR 48 −2.811 12.986 27.692 390 O TYR 48 −3.02913.582 28.747 391 N ALA 49 −2.523 11.679 27.627 392 CA ALA 49 −2.63510.824 28.761 393 CB ALA 49 −3.418 9.550 28.414 394 C ALA 49 −1.24910.416 29.096 395 O ALA 49 −0.438 10.170 28.207 396 N ILE 50 −0.87910.329 30.379 397 CA ILE 50 0.376 9.667 30.389 398 CB ILE 50 1.47110.267 31.209 399 CG2 ILE 50 1.580 9.544 32.563 400 CG1 ILE 50 2.73110.166 30.319 401 CD1 ILE 50 3.639 11.387 30.402 402 C ILE 50 0.1618.252 30.758 403 O ILE 50 −0.922 7.858 31.180 404 N GLY 51 1.206 7.43230.541 405 CA GLY 51 1.120 6.031 30.809 406 C GLY 51 0.792 5.361 29.513407 O GLY 51 1.455 5.605 28.502 408 N THR 52 −0.258 4.500 29.526 409 CATHR 52 −0.807 4.056 28.280 410 CB THR 52 −2.098 3.280 28.339 411 OG1 THR52 −3.056 3.842 27.444 412 CG2 THR 52 −2.646 3.303 29.770 413 C THR 52−1.097 5.297 27.566 414 O THR 52 −1.877 6.139 28.014 415 N GLN 53 −0.3925.463 26.451 416 CA GLN 53 −0.440 6.751 25.887 417 CB GLN 53 0.644 7.06124.864 418 CG GLN 53 2.063 6.841 25.358 419 CD GLN 53 2.888 7.250 24.159420 OE1 GLN 53 4.105 7.088 24.128 421 NE2 GLN 53 2.184 7.791 23.132 422C GLN 53 −1.683 6.811 25.120 423 O GLN 53 −2.221 5.816 24.641 424 N GLN54 −2.153 8.041 24.990 425 CA GLN 54 −3.278 8.289 24.183 426 CB GLN 54−4.511 7.472 24.608 427 CG GLN 54 −5.606 7.348 23.547 428 CD GLN 54−6.643 6.386 24.116 429 OE1 GLN 54 −7.711 6.172 23.546 430 NE2 GLN 54−6.321 5.794 25.296 431 C GLN 54 −3.550 9.700 24.490 432 O GLN 54 −3.05310.233 25.479 433 N ALA 55 −4.327 10.340 23.622 434 CA ALA 55 −4.89411.580 23.989 435 CB ALA 55 −4.370 12.750 23.148 436 C ALA 55 −6.31311.363 23.677 437 O ALA 55 −6.661 10.378 23.034 438 N THR 56 −7.18612.242 24.162 439 CA THR 56 −8.550 11.885 24.010 440 CB THR 56 −8.87310.672 24.844 441 OG1 THR 56 −10.254 10.591 25.154 442 CG2 THR 56 −8.02310.706 26.129 443 C THR 56 −9.290 13.090 24.447 444 O THR 56 −9.12013.570 25.565 445 N PRO 57 −10.044 13.675 23.564 446 CA PRO 57 −10.42015.036 23.724 447 CD PRO 57 −10.492 13.080 22.319 448 CB PRO 57 −11.02915.490 22.409 449 CG PRO 57 −10.995 14.262 21.460 450 C PRO 57 −11.48014.994 24.736 451 O PRO 57 −11.971 13.910 25.043 452 N GLY 58 −11.91016.175 25.177 453 CA GLY 58 −13.282 16.229 25.514 454 C GLY 58 −13.98516.846 24.360 455 O GLY 58 −13.744 16.638 23.170 456 N PRO 59 −14.88417.624 24.839 457 CA PRO 59 −16.089 17.881 24.116 458 CD PRO 59 −15.09317.523 26.270 459 CB PRO 59 −17.218 17.796 25.150 460 CG PRO 59 −16.59217.292 26.460 461 C PRO 59 −16.050 19.229 23.485 462 O PRO 59 −17.02419.598 22.832 463 N ALA 60 −14.989 20.016 23.716 464 CA ALA 60 −15.12321.412 23.422 465 CB ALA 60 −14.366 22.338 24.387 466 C ALA 60 −14.58721.677 22.054 467 O ALA 60 −14.779 20.882 21.134 468 N ASN 61 −13.92622.838 21.871 469 CA ASN 61 −13.568 23.153 20.528 470 CB ASN 61 −13.42924.641 20.200 471 CG ASN 61 −14.192 24.798 18.894 472 OD1 ASN 61 −14.81625.821 18.610 473 ND2 ASN 61 −14.167 23.715 18.067 474 C ASN 61 −12.29622.464 20.207 475 O ASN 61 −11.276 22.613 20.882 476 N SER 62 −12.37321.645 19.147 477 CA SER 62 −11.304 20.831 18.682 478 CB SER 62 −11.78219.416 18.336 479 OG SER 62 −10.997 18.457 19.023 480 C SER 62 −10.90921.434 17.391 481 O SER 62 −10.179 20.814 16.620 482 N GLY 63 −11.44422.648 17.143 483 CA GLY 63 −11.533 23.269 15.858 484 C GLY 63 −10.24423.088 15.150 485 O GLY 63 −10.153 22.353 14.165 486 N ARG 64 −9.19423.727 15.686 487 CA ARG 64 −7.881 23.391 15.239 488 CB ARG 64 −7.38524.286 14.098 489 CG ARG 64 −8.508 25.171 13.560 490 CD ARG 64 −8.51826.598 14.121 491 NE ARG 64 −9.750 26.780 14.938 492 CZ ARG 64 −9.64326.996 16.301 493 NH1 ARG 64 −8.419 27.067 16.883 494 NH2 ARG 64 −10.77227.132 17.047 495 C ARG 64 −6.994 23.599 16.418 496 O ARG 64 −6.60324.726 16.714 497 N GLU 65 −6.648 22.507 17.126 498 CA GLU 65 −5.61722.582 18.122 499 CB GLU 65 −6.106 23.055 19.503 500 CG GLU 65 −6.59724.511 19.500 501 CD GLU 65 −8.108 24.492 19.362 502 OE1 GLU 65 −8.66423.428 18.984 503 OE2 GLU 65 −8.734 25.543 19.667 504 C GLU 65 −5.06021.198 18.239 505 O GLU 65 −5.610 20.257 17.669 506 N THR 66 −3.92321.048 18.960 507 CA THR 66 −3.216 19.804 19.076 508 CB THR 66 −2.10519.651 18.080 509 OG1 THR 66 −2.521 20.080 16.788 510 CG2 THR 66 −1.66318.177 18.035 511 C THR 66 −2.528 19.827 20.407 512 O THR 66 −2.33520.893 20.985 513 N ILE 67 −2.112 18.655 20.930 514 CA ILE 67 −1.35618.719 22.147 515 CB ILE 67 −2.043 18.118 23.342 516 CG2 ILE 67 −1.94416.584 23.247 517 CG1 ILE 67 −1.455 18.697 24.634 518 CD1 ILE 67 −2.24718.344 25.891 519 C ILE 67 −0.069 17.986 21.962 520 O ILE 67 0.04017.062 21.156 521 N TYR 68 0.955 18.396 22.736 522 CA TYR 68 2.20017.694 22.765 523 CB TYR 68 3.443 18.590 22.780 524 CG TYR 68 3.52319.043 21.384 525 CD1 TYR 68 4.224 18.313 20.463 526 CD2 TYR 68 2.85120.176 21.004 527 CE1 TYR 68 4.277 18.737 19.161 528 CE2 TYR 68 2.89820.608 19.697 529 CZ TYR 68 3.617 19.886 18.778 530 OH TYR 68 3.66220.322 17.433 531 C TYR 68 2.253 16.944 24.038 532 O TYR 68 1.792 17.38625.090 533 N PRO 69 2.882 15.824 23.933 534 CA PRO 69 3.202 15.03825.069 535 CD PRO 69 2.915 15.073 22.691 536 CB PRO 69 3.936 13.81324.523 537 CG PRO 69 3.431 13.670 23.074 538 C PRO 69 4.007 15.82926.057 539 O PRO 69 3.949 15.496 27.237 540 N ASN 70 4.768 16.861 25.644541 CA ASN 70 5.568 17.531 26.632 542 CB ASN 70 6.819 18.229 26.068 543CG ASN 70 6.496 18.662 24.655 544 OD1 ASN 70 6.791 17.931 23.709 545 ND2ASN 70 5.853 19.854 24.500 546 C ASN 70 4.704 18.552 27.302 547 O ASN 705.127 19.186 28.272 548 N ALA 71 3.458 18.695 26.808 549 CA ALA 71 2.40619.425 27.463 550 CB ALA 71 2.508 19.448 28.998 551 C ALA 71 2.34620.827 26.941 552 O ALA 71 1.890 21.743 27.625 553 N SER 72 2.773 21.00025.672 554 CA SER 72 2.498 22.150 24.864 555 CB SER 72 3.436 22.27723.644 556 OG SER 72 4.602 23.045 23.915 557 C SER 72 1.134 21.91524.272 558 O SER 72 0.683 20.773 24.207 559 N LEU 73 0.452 22.994 23.813560 CA LEU 73 −0.827 22.852 23.165 561 CB LEU 73 −2.016 23.261 24.057562 CG LEU 73 −3.399 23.049 23.403 563 CD2 LEU 73 −4.471 23.969 24.011564 CD1 LEU 73 −3.781 21.557 23.396 565 C LEU 73 −0.847 23.775 21.972566 O LEU 73 −1.087 24.977 22.105 567 N LEU 74 −0.610 23.229 20.753 568CA LEU 74 −0.598 24.051 19.568 569 CB LEU 74 −0.156 23.316 18.282 570 CGLEU 74 −0.267 24.177 17.002 571 CD2 LEU 74 −0.138 23.340 15.718 572 CD1LEU 74 0.748 25.327 17.020 573 C LEU 74 −1.992 24.525 19.315 574 O LEU74 −2.935 23.734 19.335 575 N ILE 75 −2.170 25.835 19.053 576 CA ILE 75−3.502 26.177 18.666 577 CB ILE 75 −4.221 27.062 19.634 578 CG2 ILE 75−3.274 28.196 20.064 579 CG1 ILE 75 −5.545 27.515 19.002 580 CD1 ILE 75−6.379 28.415 19.905 581 C ILE 75 −3.471 26.825 17.326 582 O ILE 75−2.878 27.885 17.129 583 N GLN 76 −4.136 26.162 16.359 584 CA GLN 76−4.247 26.649 15.025 585 CB GLN 76 −4.646 25.581 14.007 586 CG GLN 76−3.712 24.375 14.018 587 CD GLN 76 −3.793 23.724 12.649 588 OE1 GLN 76−4.801 23.892 11.968 589 NE2 GLN 76 −2.734 22.979 12.236 590 C GLN 76−5.330 27.655 15.023 591 O GLN 76 −5.691 28.142 16.092 592 N ASN 77−5.828 27.970 13.806 593 CA ASN 77 −6.387 29.227 13.370 594 CB ASN 77−7.479 29.103 12.273 595 CG ASN 77 −7.018 28.322 11.026 596 OD1 ASN 77−7.583 28.495 9.948 597 ND2 ASN 77 −6.007 27.427 11.144 598 C ASN 77−6.998 29.921 14.547 599 O ASN 77 −8.032 29.494 15.056 600 N VAL 78−6.320 30.971 15.062 601 CA VAL 78 −6.584 31.388 16.413 602 CB VAL 78−5.343 31.851 17.167 603 CG1 VAL 78 −4.099 31.157 16.600 604 CG2 VAL 78−5.213 33.380 17.105 605 C VAL 78 −7.574 32.510 16.381 606 O VAL 78−8.465 32.609 17.226 607 N THR 79 −7.440 33.384 15.370 608 CA THR 79−8.198 34.592 15.248 609 CB THR 79 −9.577 34.395 14.699 610 OG1 THR 79−10.483 33.977 15.715 611 CG2 THR 79 −9.483 33.329 13.601 612 C THR 79−8.320 35.286 16.568 613 O THR 79 −7.595 35.007 17.519 614 N GLN 80−9.249 36.262 16.615 615 CA GLN 80 −9.376 37.212 17.684 616 CB GLN 80−9.973 38.543 17.223 617 CG GLN 80 −11.491 38.579 17.400 618 CD GLN 80−11.834 39.953 17.929 619 OE1 GLN 80 −12.718 40.121 18.766 620 NE2 GLN80 −11.093 40.979 17.432 621 C GLN 80 −10.353 36.651 18.656 622 O GLN 80−10.398 37.032 19.826 623 N ASN 81 −11.180 35.716 18.178 624 CA ASN 81−12.133 35.122 19.047 625 CB ASN 81 −12.973 34.046 18.346 626 CG ASN 81−14.287 34.699 17.923 627 OD1 ASN 81 −15.084 34.153 17.159 628 ND2 ASN81 −14.523 35.928 18.453 629 C ASN 81 −11.359 34.475 20.138 630 O ASN 81−11.593 34.734 21.316 631 N ASP 82 −10.404 33.604 19.767 632 CA ASP 82−9.833 32.726 20.737 633 CB ASP 82 −9.205 31.481 20.100 634 CG ASP 82−10.386 30.651 19.647 635 OD1 ASP 82 −11.519 31.193 19.745 636 OD2 ASP82 −10.191 29.477 19.230 637 C ASP 82 −8.796 33.446 21.533 638 O ASP 82−8.042 32.820 22.273 639 N THR 83 −8.749 34.787 21.448 640 CA THR 83−7.851 35.492 22.310 641 CB THR 83 −7.897 36.982 22.138 642 OG1 THR 83−6.609 37.535 22.336 643 CG2 THR 83 −8.890 37.562 23.163 644 C THR 83−8.266 35.179 23.709 645 O THR 83 −9.352 34.649 23.933 646 N GLY 84−7.413 35.488 24.702 647 CA GLY 84 −7.838 35.281 26.051 648 C GLY 84−6.994 34.236 26.684 649 O GLY 84 −6.137 33.627 26.051 650 N PHE 85−7.231 34.030 27.992 651 CA PHE 85 −6.397 33.238 28.854 652 CB PHE 85−6.517 33.701 30.318 653 CG PHE 85 −6.046 32.659 31.298 654 CD1 PHE 85−4.767 32.704 31.776 655 CD2 PHE 85 −6.900 31.689 31.741 656 CE1 PHE 85−4.323 31.753 32.688 657 CE2 PHE 85 −6.471 30.734 32.647 658 CZ PHE 85−5.187 30.780 33.136 659 C PHE 85 −6.876 31.828 28.765 660 O PHE 85−8.080 31.576 28.717 661 N TYR 86 −5.926 30.871 28.763 662 CA TYR 86−6.273 29.500 28.973 663 CB TYR 86 −5.940 28.538 27.802 664 CG TYR 86−6.581 28.958 26.506 665 CD1 TYR 86 −6.710 30.277 26.126 666 CD2 TYR 86−7.044 27.984 25.643 667 CE1 TYR 86 −7.292 30.622 24.922 668 CE2 TYR 86−7.626 28.318 24.440 669 CZ TYR 86 −7.753 29.635 24.078 670 OH TYR 86−8.350 29.950 22.836 671 C TYR 86 −5.426 29.078 30.120 672 O TYR 86−4.471 29.754 30.498 673 N THR 87 −5.765 27.928 30.718 674 CA THR 87−4.995 27.432 31.810 675 CB THR 87 −5.724 27.415 33.120 676 OG1 THR 87−4.842 27.050 34.170 677 CG2 THR 87 −6.839 26.368 33.004 678 C THR 87−4.758 25.996 31.496 679 O THR 87 −5.291 25.467 30.524 680 N LEU 88−3.955 25.326 32.328 681 CA LEU 88 −3.808 23.925 32.086 682 CB LEU 88−2.394 23.538 31.660 683 CG LEU 88 −2.248 22.027 31.439 684 CD2 LEU 88−0.946 21.529 32.082 685 CD1 LEU 88 −2.419 21.666 29.955 686 C LEU 88−4.070 23.210 33.358 687 O LEU 88 −3.830 23.751 34.435 688 N GLN 89−4.571 21.963 33.265 689 CA GLN 89 −4.646 21.182 34.451 690 CB GLN 89−6.057 20.811 34.918 691 CG GLN 89 −6.094 20.204 36.330 692 CD GLN 89−7.509 20.311 36.904 693 OE1 GLN 89 −7.734 20.967 37.921 694 NE2 GLN 89−8.494 19.638 36.244 695 C GLN 89 −3.927 19.906 34.180 696 O GLN 89−3.508 19.612 33.063 697 N VAL 90 −3.700 19.147 35.263 698 CA VAL 90−2.942 17.928 35.255 699 CB VAL 90 −1.454 18.140 35.160 700 CG1 VAL 90−0.880 17.340 33.980 701 CG2 VAL 90 −1.164 19.659 35.117 702 C VAL 90−3.134 17.318 36.603 703 O VAL 90 −2.750 17.912 37.607 704 N ILE 91−3.727 16.117 36.697 705 CA ILE 91 −3.602 15.391 37.926 706 CB ILE 91−4.600 14.277 38.106 707 CG2 ILE 91 −5.118 14.244 39.570 708 CG1 ILE 91−5.734 14.456 37.075 709 CD1 ILE 91 −5.569 13.686 35.757 710 C ILE 91−2.316 14.660 37.834 711 O ILE 91 −1.698 14.548 36.779 712 N LYS 92−1.906 14.114 38.978 713 CA LYS 92 −1.403 12.789 38.962 714 CB LYS 920.108 12.622 39.171 715 CG LYS 92 0.952 13.898 39.275 716 CD LYS 922.360 13.651 39.827 717 CE LYS 92 2.868 14.768 40.746 718 NZ LYS 923.890 15.573 40.035 719 C LYS 92 −2.082 12.159 40.106 720 O LYS 92−2.862 12.807 40.788 721 N SER 93 −1.826 10.873 40.375 722 CA SER 93−2.558 10.409 41.503 723 CB SER 93 −2.800 8.890 41.511 724 OG SER 93−4.065 8.626 42.092 725 C SER 93 −1.763 10.774 42.706 726 O SER 93−1.221 9.889 43.378 727 N ASP 94 −1.670 12.088 43.016 728 CA ASP 94−1.002 12.443 44.232 729 CB ASP 94 0.428 11.908 44.302 730 CG ASP 940.470 11.077 45.566 731 OD1 ASP 94 0.911 9.903 45.472 732 OD2 ASP 940.048 11.593 46.636 733 C ASP 94 −0.906 13.930 44.439 734 O ASP 94−0.146 14.372 45.299 735 N LEU 95 −1.672 14.748 43.696 736 CA LEU 95−1.844 16.121 44.074 737 CB LEU 95 −0.557 16.914 44.387 738 CG LEU 95−0.663 17.839 45.627 739 CD2 LEU 95 −0.872 17.026 46.917 740 CD1 LEU 95−1.704 18.954 45.420 741 C LEU 95 −2.462 16.776 42.905 742 O LEU 95−2.208 16.409 41.760 743 N VAL 96 −3.310 17.779 43.139 744 CA VAL 96−3.832 18.353 41.950 745 CB VAL 96 −5.258 18.790 42.058 746 CG1 VAL 96−5.717 19.213 40.658 747 CG2 VAL 96 −6.065 17.602 42.592 748 C VAL 96−2.962 19.512 41.614 749 O VAL 96 −2.855 20.463 42.392 750 N ASN 97−2.306 19.451 40.436 751 CA ASN 97 −1.519 20.565 40.045 752 CB ASN 97−0.066 20.210 39.747 753 CG ASN 97 0.685 20.572 41.009 754 OD1 ASN 971.765 21.149 40.951 755 ND2 ASN 97 0.088 20.256 42.186 756 C ASN 97−2.155 21.136 38.842 757 O ASN 97 −2.296 20.491 37.802 758 N GLU 98−2.579 22.391 38.977 759 CA GLU 98 −3.261 23.033 37.913 760 CB GLU 98−4.363 23.984 38.422 761 CG GLU 98 −5.405 24.351 37.366 762 CD GLU 98−6.060 25.664 37.772 763 OE1 GLU 98 −6.542 26.366 36.842 764 OE2 GLU 98−6.112 25.973 38.995 765 C GLU 98 −2.239 23.896 37.288 766 O GLU 98−1.894 23.738 36.119 767 N GLU 99 −1.746 24.835 38.116 768 CA GLU 99−1.227 26.115 37.762 769 CB GLU 99 −0.171 26.658 38.722 770 CG GLU 990.776 27.531 37.911 771 CD GLU 99 2.125 27.507 38.600 772 OE1 GLU 992.773 26.426 38.648 773 OE2 GLU 99 2.525 28.586 39.109 774 C GLU 99−0.555 26.094 36.432 775 O GLU 99 0.298 25.250 36.149 776 N ALA 100−0.970 27.043 35.582 777 CA ALA 100 −0.398 27.237 34.286 778 CB ALA 100−0.730 26.108 33.293 779 C ALA 100 −1.073 28.479 33.797 780 O ALA 100−2.107 28.425 33.133 781 N THR 101 −0.492 29.637 34.165 782 CA THR 101−1.033 30.933 33.868 783 CB THR 101 −0.742 31.899 34.989 784 OG1 THR 101−1.618 31.638 36.083 785 CG2 THR 101 −0.895 33.343 34.513 786 C THR 101−0.333 31.387 32.633 787 O THR 101 0.750 30.903 32.328 788 N GLY 102−0.927 32.326 31.863 789 CA GLY 102 −0.260 32.758 30.663 790 C GLY 102−1.298 33.092 29.642 791 O GLY 102 −2.222 32.320 29.393 792 N GLN 103−1.160 34.281 29.033 793 CA GLN 103 −2.188 34.753 28.162 794 CB GLN 103−2.897 36.006 28.728 795 CG GLN 103 −4.028 36.564 27.861 796 CD GLN 103−4.570 37.772 28.604 797 OE1 GLN 103 −5.769 37.886 28.849 798 NE2 GLN103 −3.645 38.698 28.991 799 C GLN 103 −1.544 35.140 26.873 800 O GLN103 −0.319 35.159 26.743 801 N PHE 104 −2.378 35.457 25.869 802 CA PHE104 −1.858 36.136 24.733 803 CB PHE 104 −1.332 35.202 23.633 804 CG PHE104 −2.396 34.232 23.241 805 CD1 PHE 104 −2.448 32.999 23.840 806 CD2PHE 104 −3.329 34.543 22.277 807 CE1 PHE 104 −3.412 32.086 23.488 808CE2 PHE 104 −4.295 33.629 21.923 809 CZ PHE 104 −4.342 32.399 22.528 810C PHE 104 −2.985 36.925 24.169 811 O PHE 104 −4.122 36.815 24.619 812 NHIS 105 −2.686 37.764 23.171 813 CA HIS 105 −3.699 38.561 22.552 814 ND1HIS 105 −4.316 40.623 24.898 815 CG HIS 105 −3.250 40.546 24.028 816 CBHIS 105 −3.382 40.064 22.622 817 NE2 HIS 105 −2.523 41.325 26.026 818CD2 HIS 105 −2.166 40.982 24.733 819 CE1 HIS 105 −3.820 41.090 26.072820 C HIS 105 −3.724 38.181 21.116 821 O HIS 105 −2.810 37.509 20.643822 N VAL 106 −4.769 38.609 20.372 823 CA VAL 106 −4.764 38.447 18.941824 CB VAL 106 −6.036 37.862 18.404 825 CG1 VAL 106 −7.187 38.503 19.178826 CG2 VAL 106 −6.108 38.088 16.879 827 C VAL 106 −4.671 39.825 18.374828 O VAL 106 −5.184 40.761 18.991 829 N TYR 107 −4.003 39.981 17.213830 CA TYR 107 −3.957 41.261 16.572 831 CB TYR 107 −2.585 41.958 16.706832 CG TYR 107 −2.435 42.334 18.151 833 CD1 TYR 107 −1.993 41.432 19.094834 CD2 TYR 107 −2.743 43.603 18.571 835 CE1 TYR 107 −1.856 41.79620.418 836 CE2 TYR 107 −2.610 43.977 19.889 837 CZ TYR 107 −2.174 43.06220.824 838 OH TYR 107 −2.036 43.448 22.175 839 C TYR 107 −4.281 41.06015.120 840 O TYR 107 −3.576 40.372 14.384 841 N PRO 108 −5.389 41.67414.766 842 CA PRO 108 −5.937 41.801 13.441 843 CD PRO 108 −6.115 42.47715.740 844 CB PRO 108 −7.376 42.303 13.629 845 CG PRO 108 −7.490 42.72515.119 846 C PRO 108 −5.109 42.808 12.699 847 O PRO 108 −4.596 43.72113.340 848 N GLU 109 −4.936 42.681 11.367 849 CA GLU 109 −3.861 43.39710.720 850 CB GLU 109 −3.556 42.913 9.293 851 CG GLU 109 −3.518 41.4029.189 852 CD GLU 109 −4.941 40.951 8.923 853 OE1 GLU 109 −5.476 40.2009.782 854 OE2 GLU 109 −5.503 41.339 7.863 855 C GLU 109 −4.167 44.85610.635 856 O GLU 109 −5.104 45.337 11.260 857 N LEU 110 −3.340 45.6119.874 858 CA LEU 110 −3.490 47.035 9.916 859 CB LEU 110 −2.526 47.75510.873 860 CG LEU 110 −2.373 49.240 10.486 861 CD2 LEU 110 −0.896 49.67810.437 862 CD1 LEU 110 −3.273 50.147 11.345 863 C LEU 110 −3.265 47.6648.572 864 O LEU 110 −2.209 47.601 7.943 865 N PRO 111 −4.315 48.3488.227 866 CA PRO 111 −4.434 49.224 7.094 867 CD PRO 111 −5.570 48.1418.927 868 CB PRO 111 −5.711 50.020 7.342 869 CG PRO 111 −6.550 49.1518.299 870 C PRO 111 −3.272 50.154 6.924 871 O PRO 111 −2.423 50.2157.809 872 N LYS 112 −3.240 50.890 5.786 873 CA LYS 112 −2.272 51.9345.594 874 CB LYS 112 −1.668 52.026 4.192 875 CG LYS 112 −1.026 53.4004.037 876 CD LYS 112 −0.309 53.704 2.725 877 CE LYS 112 0.036 55.1982.670 878 NZ LYS 112 1.278 55.437 1.902 879 C LYS 112 −2.948 53.2605.763 880 O LYS 112 −3.903 53.592 5.064 881 N PRO 113 −2.418 54.0276.667 882 CA PRO 113 −2.990 55.295 7.041 883 CD PRO 113 −1.540 53.4787.686 884 CB PRO 113 −2.254 55.735 8.300 885 CG PRO 113 −1.575 54.4718.860 886 C PRO 113 −2.886 56.333 5.971 887 O PRO 113 −2.065 56.2005.062 888 N SER 114 −3.711 57.398 6.094 889 CA SER 114 −3.767 58.4645.136 890 CB SER 114 −5.007 58.376 4.228 891 OG SER 114 −5.128 59.5293.411 892 C SER 114 −3.885 59.748 5.903 893 O SER 114 −4.893 59.9866.568 894 N ILE 115 −2.844 60.609 5.814 895 CA ILE 115 −2.845 61.8896.463 896 CB ILE 115 −1.488 62.532 6.517 897 CG2 ILE 115 −1.249 63.2155.158 898 CG1 ILE 115 −1.369 63.498 7.701 899 CD1 ILE 115 −0.502 64.7267.409 900 C ILE 115 −3.680 62.791 5.608 901 O ILE 115 −4.188 62.3694.573 902 N SER 116 −3.818 64.066 6.026 903 CA SER 116 −4.328 65.0935.161 904 CB SER 116 −5.780 64.885 4.680 905 OG SER 116 −6.143 65.8973.752 906 C SER 116 −4.301 66.338 5.979 907 O SER 116 −4.918 66.4137.041 908 N SER 117 −3.528 67.339 5.518 909 CA SER 117 −3.331 68.5246.288 910 CB SER 117 −1.871 68.771 6.644 911 OG SER 117 −1.734 69.9857.368 912 C SER 117 −3.721 69.674 5.436 913 O SER 117 −3.764 69.5724.212 914 N ASN 118 −4.016 70.818 6.078 915 CA ASN 118 −4.420 71.9375.288 916 CB ASN 118 −5.637 72.699 5.855 917 CG ASN 118 −6.475 73.1084.653 918 OD1 ASN 118 −7.671 73.360 4.774 919 ND2 ASN 118 −5.837 73.1493.453 920 C ASN 118 −3.281 72.893 5.189 921 O ASN 118 −2.783 73.4066.190 922 N ASN 119 −2.858 73.160 3.939 923 CA ASN 119 −2.045 74.2833.578 924 CB ASN 119 −2.503 75.589 4.238 925 CG ASN 119 −2.412 76.6913.189 926 OD1 ASN 119 −1.805 76.493 2.138 927 ND2 ASN 119 −3.009 77.8713.495 928 C ASN 119 −0.596 74.046 3.859 929 O ASN 119 −0.161 74.0125.006 930 N SER 120 0.176 73.907 2.764 931 CA SER 120 1.589 73.724 2.804932 CB SER 120 2.084 72.730 1.737 933 OG SER 120 3.475 72.481 1.872 934C SER 120 2.223 75.046 2.548 935 O SER 120 3.330 75.302 2.990 936 N ASN121 1.483 75.970 1.900 937 CA ASN 121 1.851 77.362 1.905 938 CB ASN 1210.884 78.187 1.013 939 CG ASN 121 1.478 78.373 −0.381 940 OD1 ASN 1211.500 79.476 −0.927 941 ND2 ASN 121 1.944 77.245 −0.985 942 C ASN 1211.811 77.836 3.342 943 O ASN 121 1.538 77.034 4.235 944 N PRO 122 2.08179.087 3.696 945 CA PRO 122 2.123 79.438 5.097 946 CD PRO 122 2.13880.242 2.812 947 CB PRO 122 2.563 80.901 5.158 948 CG PRO 122 2.72681.354 3.691 949 C PRO 122 0.735 79.253 5.648 950 O PRO 122 −0.18679.337 4.843 951 N VAL 123 0.489 78.951 6.950 952 CA VAL 123 1.17079.172 8.197 953 CB VAL 123 1.289 77.929 9.016 954 CG1 VAL 123 −0.13577.584 9.499 955 CG2 VAL 123 2.041 76.828 8.224 956 C VAL 123 2.53679.748 8.020 957 O VAL 123 3.482 79.053 7.666 958 N GLU 124 2.684 81.0558.297 959 CA GLU 124 4.022 81.545 8.327 960 CB GLU 124 4.161 83.0598.111 961 CG GLU 124 3.373 83.609 6.929 962 CD GLU 124 2.149 84.3007.513 963 OE1 GLU 124 1.394 84.959 6.747 964 OE2 GLU 124 1.959 84.1838.751 965 C GLU 124 4.484 81.221 9.677 966 O GLU 124 4.219 80.125 10.170967 N ASP 125 5.170 82.168 10.326 968 CA ASP 125 5.497 81.926 11.688 969CB ASP 125 6.661 82.783 12.205 970 CG ASP 125 7.953 82.041 11.905 971OD1 ASP 125 9.013 82.506 12.400 972 OD2 ASP 125 7.901 80.989 11.217 973C ASP 125 4.286 82.265 12.488 974 O ASP 125 3.669 83.307 12.280 975 NLYS 126 3.947 81.372 13.437 976 CA LYS 126 3.004 81.636 14.484 977 CBLYS 126 3.008 83.115 14.913 978 CG LYS 126 2.379 83.372 16.272 979 CDLYS 126 1.476 84.604 16.267 980 CE LYS 126 0.697 84.814 17.565 981 NZLYS 126 −0.112 86.049 17.460 982 C LYS 126 1.626 81.234 14.041 983 O LYS126 0.647 81.899 14.376 984 N ASP 127 1.501 80.124 13.282 985 CA ASP 1270.207 79.713 12.817 986 CB ASP 127 0.025 79.924 11.312 987 CG ASP 127−0.213 81.426 11.077 988 OD1 ASP 127 −0.391 82.194 12.065 989 OD2 ASP127 −0.231 81.835 9.891 990 C ASP 127 0.068 78.259 13.142 991 O ASP 1270.572 77.813 14.169 992 N ALA 128 −0.643 77.466 12.319 993 CA ALA 128−0.898 76.170 12.864 994 CB ALA 128 −2.186 76.103 13.696 995 C ALA 128−1.040 75.169 11.773 996 O ALA 128 −2.044 75.133 11.066 997 N VAL 129−0.051 74.275 11.634 998 CA VAL 129 −0.375 73.098 10.902 999 CB VAL 1290.779 72.160 10.698 1000 CG1 VAL 129 0.833 71.779 9.208 1001 CG2 VAL 1292.059 72.839 11.197 1002 C VAL 129 −1.386 72.404 11.736 1003 O VAL 129−1.550 72.716 12.915 1004 N ALA 130 −2.091 71.436 11.141 1005 CA ALA 130−2.805 70.497 11.938 1006 CB ALA 130 −4.221 70.957 12.312 1007 C ALA 130−2.910 69.283 11.081 1008 O ALA 130 −3.792 69.175 10.226 1009 N PHE 131−1.956 68.360 11.268 1010 CA PHE 131 −1.829 67.238 10.398 1011 CB PHE131 −0.447 66.573 10.515 1012 CG PHE 131 0.530 67.417 9.776 1013 CD1 PHE131 0.126 68.151 8.694 1014 CD2 PHE 131 1.856 67.485 10.139 1015 CE1 PHE131 0.991 68.941 7.979 1016 CE2 PHE 131 2.749 68.268 9.440 1017 CZ PHE131 2.312 69.000 8.360 1018 C PHE 131 −2.827 66.245 10.846 1019 O PHE131 −2.722 65.707 11.947 1020 N THR 132 −3.830 65.943 10.009 1021 CA THR132 −4.699 64.906 10.456 1022 CB THR 132 −6.142 65.097 10.100 1023 OG1THR 132 −6.642 66.275 10.711 1024 CG2 THR 132 −6.909 63.859 10.615 1025C THR 132 −4.246 63.636 9.821 1026 O THR 132 −3.955 63.593 8.622 1027 NCYS 133 −4.152 62.559 10.608 1028 CA CYS 133 −3.922 61.266 10.036 1029CB CYS 133 −2.942 60.392 10.838 1030 SC CYS 133 −2.951 58.665 10.2711031 C CYS 133 −5.241 60.594 10.093 1032 O CYS 133 −6.033 60.825 11.0061033 N GLU 134 −5.520 59.744 9.092 1034 CA GLU 134 −6.749 59.014 9.1011035 CB GLU 134 −7.682 59.319 7.908 1036 CG GLU 134 −8.100 60.783 7.8021037 CD GLU 134 −9.098 60.900 6.674 1038 OE1 GLU 134 −10.190 61.4826.905 1039 OE2 GLU 134 −8.773 60.422 5.555 1040 C GLU 134 −6.450 57.5499.050 1041 O GLU 134 −5.434 57.077 8.537 1042 N PRO 135 −7.380 56.8649.660 1043 CA PRO 135 −7.075 55.513 10.054 1044 CD PRO 135 −7.905 57.60010.790 1045 CB PRO 135 −6.586 55.635 11.490 1046 CG PRO 135 −7.09957.022 11.968 1047 C PRO 135 −8.362 54.736 10.005 1048 O PRO 135 −9.42755.331 10.160 1049 N GLU 136 −8.346 53.407 9.800 1050 CA GLU 136 −9.64952.818 9.896 1051 CB GLU 136 −10.376 52.575 8.548 1052 CG GLU 136−11.617 53.483 8.423 1053 CD GLU 136 −12.565 53.099 7.278 1054 OE1 GLU136 −12.914 53.996 6.461 1055 OE2 GLU 136 −12.983 51.914 7.221 1056 CGLU 136 −9.553 51.505 10.596 1057 O GLU 136 −10.222 50.558 10.188 1058 NTHR 137 −8.735 51.413 11.672 1059 CA THR 137 −8.555 50.136 12.314 1060CB THR 137 −7.333 49.449 11.789 1061 OG1 THR 137 −6.803 48.563 12.7621062 CG2 THR 137 −6.297 50.531 11.417 1063 C THR 137 −8.423 50.28513.813 1064 O THR 137 −7.390 50.702 14.332 1065 N GLN 138 −9.493 49.91514.558 1066 CA GLN 138 −9.538 50.128 15.980 1067 CB GLN 138 −10.97950.085 16.552 1068 CG GLN 138 −11.079 49.776 18.050 1069 CD GLN 138−12.187 48.738 18.201 1070 OE1 GLN 138 −12.483 48.242 19.286 1071 NE2GLN 138 −12.813 48.378 17.052 1072 C GLN 138 −8.687 49.117 16.711 1073 OGLN 138 −9.020 47.940 16.808 1074 N ASP 139 −7.565 49.630 17.255 1075 CAASP 139 −6.583 49.099 18.178 1076 CB ASP 139 −6.644 47.605 18.628 1077CG ASP 139 −5.732 47.470 19.878 1078 OD1 ASP 139 −6.194 46.962 20.9361079 OD2 ASP 139 −4.546 47.884 19.787 1080 C ASP 139 −5.271 49.39417.542 1081 O ASP 139 −5.055 49.099 16.368 1082 N THR 140 −4.407 50.10718.292 1083 CA THR 140 −3.631 51.132 17.641 1084 CB THR 140 −4.40752.367 17.431 1085 OG1 THR 140 −4.937 52.755 18.684 1086 CG2 THR 140−5.527 52.110 16.425 1087 C THR 140 −2.571 51.650 18.555 1088 O THR 140−2.653 51.493 19.770 1089 N THR 141 −1.561 52.368 18.002 1090 CA THR 141−0.618 53.006 18.881 1091 CB THR 141 0.149 51.989 19.689 1092 OG1 THR141 1.310 52.535 20.301 1093 CG2 THR 141 0.540 50.850 18.751 1094 C THR141 0.281 53.864 18.036 1095 O THR 141 1.433 53.528 17.738 1096 N TYR142 −0.281 55.018 17.629 1097 CA TYR 142 0.070 55.839 16.497 1098 CB TYR142 −1.127 56.763 16.224 1099 CG TYR 142 −0.879 57.717 15.118 1100 CD1TYR 142 −0.195 57.351 13.985 1101 CD2 TYR 142 −1.341 59.003 15.241 1102CE1 TYR 142 0.018 58.246 12.960 1103 CE2 TYR 142 −1.136 59.901 14.2241104 CZ TYR 142 −0.453 59.530 13.091 1105 OH TYR 142 −0.258 60.48112.068 1106 C TYR 142 1.264 56.679 16.841 1107 O TYR 142 1.370 57.13817.976 1108 N LEU 143 2.184 56.912 15.871 1109 CA LEU 143 3.279 57.80716.130 1110 CB LEU 143 4.672 57.151 15.999 1111 CG LEU 143 5.150 56.40817.261 1112 CD2 LEU 143 5.388 54.914 16.985 1113 CD1 LEU 143 4.19656.660 18.435 1114 C LEU 143 3.237 58.921 15.135 1115 O LEU 143 2.57858.819 14.095 1116 N TRP 144 3.951 60.029 15.421 1117 CA TRP 144 4.12861.072 14.446 1118 CB TRP 144 3.815 62.470 15.014 1119 CG TRP 144 2.34062.794 15.029 1120 CD2 TRP 144 1.644 63.221 13.846 1121 CD1 TRP 1441.412 62.734 16.030 1122 NE1 TRP 144 0.170 63.065 15.536 1123 CE2 TRP144 0.304 63.367 14.198 1124 CE3 TRP 144 2.088 63.455 12.580 1125 CZ2TRP 144 −0.625 63.744 13.265 1126 CZ3 TRP 144 1.159 63.850 11.653 1127CH2 TRP 144 −0.175 63.990 11.991 1128 C TRP 144 5.575 61.022 14.049 1129O TRP 144 6.373 60.429 14.776 1130 N TRP 145 5.968 61.609 12.894 1131 CATRP 145 7.367 61.580 12.543 1132 CB TRP 145 7.841 60.250 11.889 1133 CGTRP 145 7.369 58.918 12.469 1134 CD2 TRP 145 7.866 58.298 13.679 1135CD1 TRP 145 6.458 58.042 11.947 1136 NE1 TRP 145 6.367 56.921 12.7361137 CE2 TRP 145 7.224 57.062 13.808 1138 CE3 TRP 145 8.792 58.71014.602 1139 CZ2 TRP 145 7.495 56.226 14.848 1140 CZ3 TRP 145 9.04457.860 15.660 1141 CH2 TRP 145 8.416 56.639 15.781 1142 C TRP 145 7.66762.697 11.558 1143 O TRP 145 6.796 63.125 10.796 1144 N ILE 146 8.92963.211 11.588 1145 CA ILE 146 9.384 64.301 10.756 1146 CB ILE 146 9.59365.594 11.491 1147 CG2 ILE 146 10.050 65.253 12.910 1148 CG1 ILE 14610.584 66.476 10.727 1149 CD1 ILE 146 11.308 67.487 11.605 1150 C ILE146 10.716 63.948 10.155 1151 O ILE 146 11.567 63.339 10.806 1152 N ASN147 10.922 64.364 8.884 1153 CA ASN 147 12.031 64.003 8.030 1154 CB ASN147 13.335 64.777 8.299 1155 CG ASN 147 13.123 66.211 7.824 1156 OD1 ASN147 13.176 66.513 6.634 1157 ND2 ASN 147 12.859 67.120 8.794 1158 C ASN147 12.289 62.538 8.137 1159 O ASN 147 13.407 62.070 7.921 1160 N ASN148 11.233 61.769 8.445 1161 CA ASN 148 11.361 60.351 8.515 1162 CB ASN148 11.800 59.755 7.161 1163 CG ASN 148 11.819 58.235 7.206 1164 OD1 ASN148 12.857 57.621 6.963 1165 ND2 ASN 148 10.658 57.612 7.550 1166 C ASN148 12.379 60.056 9.558 1167 O ASN 148 13.111 59.077 9.468 1168 N GLN149 12.427 60.881 10.616 1169 CA GLN 149 13.099 60.403 11.776 1170 CBGLN 149 14.621 60.360 11.671 1171 CG GLN 149 15.191 59.277 12.586 1172CD GLN 149 16.712 59.395 12.604 1173 OE1 GLN 149 17.255 60.477 12.3851174 NE2 GLN 149 17.402 58.263 12.901 1175 C GLN 149 12.753 61.24012.962 1176 O GLN 149 13.362 62.274 13.224 1177 N SER 150 11.792 60.75813.765 1178 CA SER 150 11.660 61.156 15.136 1179 CB SER 150 13.00161.274 15.878 1180 OG SER 150 13.394 59.986 16.315 1181 C SER 150 10.96862.457 15.261 1182 O SER 150 11.252 63.385 14.510 1183 N LEU 151 10.07062.564 16.261 1184 CA LEU 151 9.613 63.878 16.561 1185 CB LEU 151 8.32064.283 15.856 1186 CG LEU 151 8.054 65.789 16.078 1187 CD2 LEU 151 6.85866.324 15.282 1188 CD1 LEU 151 9.323 66.625 15.839 1189 C LEU 151 9.37764.000 18.028 1190 O LEU 151 8.231 64.008 18.488 1191 N PRO 152 10.46164.195 18.733 1192 CA PRO 152 10.451 65.338 19.586 1193 CD PRO 15211.704 64.227 17.974 1194 CB PRO 152 10.911 66.441 18.667 1195 CG PRO152 12.000 65.728 17.830 1196 C PRO 152 9.354 65.655 20.582 1197 O PRO152 9.629 65.554 21.780 1198 N VAL 153 8.140 66.097 20.164 1199 CA VAL153 7.144 66.818 20.956 1200 CB VAL 153 6.193 66.086 21.874 1201 CG1 VAL153 5.605 67.152 22.830 1202 CG2 VAL 153 5.103 65.312 21.126 1203 C VAL153 7.778 67.785 21.894 1204 O VAL 153 8.354 67.445 22.928 1205 N SER154 7.614 69.063 21.565 1206 CA SER 154 8.202 70.059 22.390 1207 CB SER154 9.424 70.660 21.717 1208 OG SER 154 9.461 70.231 20.363 1209 C SER154 7.141 71.088 22.471 1210 O SER 154 6.263 71.053 21.611 1211 N PRO155 7.129 71.951 23.467 1212 CA PRO 155 5.859 72.359 24.012 1213 CD PRO155 8.140 71.923 24.518 1214 CB PRO 155 6.186 73.305 25.168 1215 CG PRO155 7.549 72.788 25.678 1216 C PRO 155 4.847 72.870 23.044 1217 O PRO155 3.657 72.621 23.252 1218 N ARG 156 5.241 73.546 21.960 1219 CA ARG156 4.234 74.145 21.126 1220 CB ARG 156 4.768 75.000 19.970 1221 CG ARG156 6.278 75.067 19.905 1222 CD ARG 156 6.766 75.606 18.569 1223 NE ARG156 7.413 74.490 17.802 1224 CZ ARG 156 7.879 74.722 16.544 1225 NH1 ARG156 7.598 75.914 15.921 1226 NH2 ARG 156 8.652 73.797 15.895 1227 C ARG156 3.391 73.108 20.468 1228 O ARG 156 2.324 73.428 19.938 1229 N LEU157 3.826 71.839 20.457 1230 CA LEU 157 2.977 70.955 19.718 1231 CB LEU157 3.629 69.616 19.301 1232 CG LEU 157 4.773 69.785 18.283 1233 CD2 LEU157 5.285 68.437 17.732 1234 CD1 LEU 157 5.906 70.640 18.868 1235 C LEU157 1.762 70.664 20.546 1236 O LEU 157 1.756 70.892 21.755 1237 N GLN158 0.678 70.176 19.907 1238 CA GLN 158 −0.417 69.590 20.628 1239 CB GLN158 −1.700 70.445 20.737 1240 CG GLN 158 −2.746 69.805 21.654 1241 CDGLN 158 −4.120 70.450 21.479 1242 OE1 GLN 158 −5.029 70.129 22.243 1243NE2 GLN 158 −4.281 71.370 20.491 1244 C GLN 158 −0.827 68.410 19.8231245 O GLN 158 −0.592 68.339 18.618 1246 N LEU 159 −1.478 67.443 20.4761247 CA LEU 159 −2.092 66.411 19.711 1248 CB LEU 159 −1.124 65.25019.442 1249 CG LEU 159 −0.095 65.059 20.572 1250 CD2 LEU 159 1.17064.355 20.063 1251 CD1 LEU 159 −0.707 64.375 21.815 1252 C LEU 159−3.213 65.931 20.559 1253 O LEU 159 −3.132 65.996 21.780 1254 N SER 160−4.319 65.453 19.962 1255 CA SER 160 −5.327 64.916 20.827 1256 CB SER160 −6.367 65.955 21.304 1257 OG SER 160 −6.954 66.625 20.200 1258 C SER160 −6.022 63.840 20.062 1259 O SER 160 −5.645 63.527 18.937 1260 N ASN161 −7.065 63.252 20.665 1261 CA ASN 161 −7.913 62.384 19.916 1262 CBASN 161 −8.480 63.062 18.660 1263 CG ASN 161 −9.968 63.259 18.832 1264OD1 ASN 161 −10.693 63.578 17.887 1265 ND2 ASN 161 −10.453 63.051 20.0901266 C ASN 161 −7.131 61.203 19.425 1267 O ASN 161 −7.281 60.814 18.2681268 N GLY 162 −6.293 60.591 20.284 1269 CA GLY 162 −5.693 59.323 19.9821270 C GLY 162 −4.555 59.525 19.025 1271 O GLY 162 −4.356 58.736 18.1041272 N ASN 163 −3.786 60.612 19.239 1273 CA ASN 163 −2.645 61.015 18.4541274 CB ASN 163 −1.567 59.946 18.220 1275 CG ASN 163 −0.936 59.46319.510 1276 OD1 ASN 163 −1.205 58.313 19.854 1277 ND2 ASN 163 −0.08960.291 20.194 1278 C ASN 163 −3.061 61.357 17.075 1279 O ASN 163 −2.22061.793 16.289 1280 N ARG 164 −4.328 61.123 16.719 1281 CA ARG 164 −4.67161.193 15.337 1282 CB ARG 164 −6.150 60.870 15.167 1283 CG ARG 164−6.575 60.616 13.738 1284 CD ARG 164 −8.095 60.641 13.630 1285 NE ARG164 −8.445 61.816 12.814 1286 CZ ARG 164 −9.480 61.697 11.942 1287 NH1ARG 164 −9.850 62.747 11.170 1288 NH2 ARG 164 −10.144 60.511 11.868 1289C ARG 164 −4.429 62.602 14.907 1290 O ARG 164 −3.640 62.875 14.005 1291N THR 165 −5.101 63.536 15.602 1292 CA THR 165 −5.025 64.925 15.296 1293CB THR 165 −6.118 65.718 15.934 1294 OG1 THR 165 −6.042 65.578 17.3431295 CG2 THR 165 −7.463 65.223 15.398 1296 C THR 165 −3.775 65.45615.893 1297 O THR 165 −3.466 65.182 17.049 1298 N LEU 166 −3.021 66.25915.126 1299 CA LEU 166 −1.930 66.979 15.714 1300 CB LEU 166 −0.54166.423 15.350 1301 CG LEU 166 0.557 67.483 15.162 1302 CD2 LEU 166 1.61567.004 14.162 1303 CD1 LEU 166 1.147 67.941 16.515 1304 C LEU 166 −2.00768.359 15.172 1305 O LEU 166 −2.498 68.589 14.067 1306 N THR 167 −1.55269.339 15.968 1307 CA THR 167 −1.668 70.677 15.477 1308 CB THR 167−2.855 71.391 16.041 1309 OG1 THR 167 −2.562 72.780 16.154 1310 CG2 THR167 −3.169 70.815 17.430 1311 C THR 167 −0.465 71.391 15.962 1312 O THR167 −0.181 71.396 17.158 1313 N LEU 168 0.289 72.022 15.049 1314 CA LEU168 1.290 72.859 15.600 1315 CB LEU 168 2.606 72.937 14.805 1316 CG LEU168 3.782 73.227 15.755 1317 CD2 LEU 168 5.131 73.221 15.017 1318 CD1LEU 168 3.720 72.297 16.979 1319 C LEU 168 0.723 74.225 15.676 1320 OLEU 168 −0.260 74.543 14.991 1321 N LEU 169 1.317 75.042 16.553 1322 CALEU 169 0.882 76.376 16.804 1323 CB LEU 169 −0.632 76.460 17.083 1324 CGLEU 169 −1.072 77.683 17.912 1325 CD2 LEU 169 −2.608 77.791 17.936 1326CD1 LEU 169 −0.375 78.974 17.461 1327 C LEU 169 1.623 76.775 18.025 1328O LEU 169 1.399 76.228 19.104 1329 N SER 170 2.552 77.726 17.860 1330 CASER 170 2.780 78.205 16.538 1331 CB SER 170 3.523 79.556 16.507 1332 OGSER 170 4.895 79.374 16.206 1333 C SER 170 3.625 77.173 15.866 1334 OSER 170 3.979 76.150 16.452 1335 N VAL 171 3.975 77.413 14.596 1336 CAVAL 171 4.955 76.597 13.951 1337 CB VAL 171 4.426 75.975 12.690 1338 CG1VAL 171 4.238 77.095 11.648 1339 CG2 VAL 171 5.332 74.814 12.231 1340 CVAL 171 6.053 77.555 13.620 1341 O VAL 171 5.907 78.760 13.837 1342 NTHR 172 7.204 77.082 13.127 1343 CA THR 172 8.229 78.059 12.932 1344 CBTHR 172 9.369 77.930 13.923 1345 OG1 THR 172 10.238 79.044 13.809 1346CG2 THR 172 10.116 76.587 13.752 1347 C THR 172 8.726 77.950 11.525 1348O THR 172 7.946 77.812 10.582 1349 N ARG 173 10.055 78.037 11.351 1350CA ARG 173 10.712 77.906 10.090 1351 CB ARG 173 11.891 78.869 10.0371352 CG ARG 173 12.246 79.290 11.463 1353 CD ARG 173 13.280 80.39611.594 1354 NE ARG 173 14.249 79.943 12.637 1355 CZ ARG 173 15.56380.299 12.526 1356 NH1 ARG 173 15.944 81.135 11.512 1357 NH2 ARG 17316.487 79.825 13.412 1358 C ARG 173 11.300 76.529 10.069 1359 O ARG 17311.664 76.003 9.020 1360 N ASN 174 11.435 75.925 11.265 1361 CA ASN 17412.241 74.748 11.421 1362 CB ASN 174 12.724 74.557 12.864 1363 CG ASN174 13.733 73.424 12.886 1364 OD1 ASN 174 13.783 72.684 13.866 1365 ND2ASN 174 14.514 73.254 11.780 1366 C ASN 174 11.447 73.537 11.064 1367 OASN 174 11.954 72.418 11.058 1368 N ASP 175 10.154 73.725 10.772 1369 CAASP 175 9.361 72.570 10.490 1370 CB ASP 175 7.976 72.613 11.181 1371 CGASP 175 8.210 73.012 12.643 1372 OD1 ASP 175 8.634 74.179 12.858 1373OD2 ASP 175 7.979 72.175 13.557 1374 C ASP 175 9.220 72.534 9.002 1375 OASP 175 8.140 72.704 8.444 1376 N THR 176 10.382 72.352 8.335 1377 CATHR 176 10.522 72.428 6.910 1378 CB THR 176 11.714 73.259 6.495 1379 OG1THR 176 12.039 73.014 5.127 1380 CG2 THR 176 12.900 72.886 7.416 1381 CTHR 176 10.769 71.025 6.460 1382 O THR 176 11.903 70.559 6.356 1383 NGLY 177 9.684 70.284 6.206 1384 CA GLY 177 9.890 68.928 5.832 1385 C GLY177 8.569 68.236 5.912 1386 O GLY 177 7.613 68.622 6.587 1387 N PRO 1788.569 67.174 5.196 1388 CA PRO 178 7.407 66.352 5.100 1389 CD PRO 1789.530 66.962 4.138 1390 CB PRO 178 7.687 65.364 3.979 1391 CG PRO 1788.871 65.955 3.190 1392 C PRO 178 7.170 65.663 6.399 1393 O PRO 1788.125 65.312 7.093 1394 N TYR 179 5.893 65.439 6.744 1395 CA TYR 1795.615 64.802 7.988 1396 CB TYR 179 4.871 65.704 8.979 1397 CG TYR 1795.887 66.576 9.640 1398 CD1 TYR 179 6.052 66.541 11.007 1399 CD2 TYR 1796.677 67.435 8.900 1400 CE1 TYR 179 6.987 67.336 11.624 1401 CE2 TYR 1797.609 68.230 9.512 1402 CZ TYR 179 7.768 68.191 10.879 1403 OH TYR 1798.728 68.999 11.511 1404 C TYR 179 4.736 63.637 7.705 1405 O TYR 1793.547 63.787 7.422 1406 N GLU 180 5.336 62.436 7.776 1407 CA GLU 1804.658 61.203 7.559 1408 CB GLU 180 5.624 60.064 7.207 1409 CG GLU 1804.982 58.850 6.546 1410 CD GLU 180 6.055 58.282 5.622 1411 OE1 GLU 1807.232 58.252 6.070 1412 OE2 GLU 180 5.738 57.899 4.463 1413 C GLU 1804.020 60.855 8.862 1414 O GLU 180 4.252 61.509 9.876 1415 N CYS 1813.189 59.801 8.852 1416 CA CYS 181 2.527 59.300 10.017 1417 CB CYS 1810.984 59.317 9.873 1418 SG CYS 181 0.219 57.783 9.238 1419 C CYS 1813.008 57.894 10.154 1420 O CYS 181 3.934 57.487 9.452 1421 N GLU 1822.414 57.108 11.071 1422 CA GLU 182 2.772 55.724 11.127 1423 CB GLU 1824.246 55.464 11.503 1424 CG GLU 182 5.015 54.612 10.480 1425 CD GLU 1825.648 53.403 11.166 1426 OE1 GLU 182 6.157 53.562 12.305 1427 OE2 GLU182 5.643 52.295 10.564 1428 C GLU 182 1.965 55.133 12.220 1429 O GLU182 2.258 55.353 13.391 1430 N ILE 183 0.928 54.353 11.885 1431 CA ILE183 0.287 53.679 12.964 1432 CB ILE 183 −1.111 53.259 12.650 1433 CG2ILE 183 −1.782 52.867 13.969 1434 CG1 ILE 183 −1.832 54.401 11.909 1435CD1 ILE 183 −3.267 54.629 12.377 1436 C ILE 183 1.144 52.497 13.260 1437O ILE 183 2.151 52.286 12.587 1438 N GLN 184 0.802 51.700 14.296 1439 CAGLN 184 1.638 50.567 14.581 1440 CB GLN 184 2.669 50.802 15.705 1441 CGGLN 184 4.056 50.225 15.390 1442 CD GLN 184 4.927 50.193 16.649 1443 OE1GLN 184 5.396 49.137 17.072 1444 NE2 GLN 184 5.168 51.383 17.261 1445 CGLN 184 0.741 49.476 15.063 1446 O GLN 184 −0.396 49.344 14.614 1447 NASN 185 1.276 48.684 16.014 1448 CA ASN 185 0.633 47.649 16.776 1449 CBASN 185 −0.604 47.002 16.082 1450 CG ASN 185 −0.273 45.722 15.314 1451OD1 ASN 185 −0.708 44.623 15.666 1452 ND2 ASN 185 0.493 45.873 14.2051453 C ASN 185 1.726 46.652 17.029 1454 O ASN 185 2.874 46.979 16.7341455 N PRO 186 1.505 45.481 17.558 1456 CA PRO 186 2.571 44.523 17.6581457 CD PRO 186 0.300 45.078 18.258 1458 CB PRO 186 1.982 43.260 18.2961459 CG PRO 186 0.619 43.711 18.878 1460 C PRO 186 3.065 44.285 16.2701461 O PRO 186 2.232 44.162 15.374 1462 N VAL 187 4.407 44.251 16.0911463 CA VAL 187 5.150 44.369 14.864 1464 CB VAL 187 6.318 43.418 14.7631465 CG1 VAL 187 7.326 44.001 13.758 1466 CG2 VAL 187 6.881 43.12916.166 1467 C VAL 187 4.315 44.145 13.642 1468 O VAL 187 4.443 43.10712.987 1469 N SER 188 3.459 45.116 13.273 1470 CA SER 188 2.970 45.17511.927 1471 CB SER 188 1.711 44.342 11.669 1472 OG SER 188 2.074 42.96911.676 1473 C SER 188 2.633 46.598 11.696 1474 O SER 188 2.118 47.27212.589 1475 N ALA 189 2.965 47.116 10.500 1476 CA ALA 189 2.863 48.53510.358 1477 CB ALA 189 4.180 49.263 10.665 1478 C ALA 189 2.549 48.8638.937 1479 O ALA 189 2.902 48.122 8.020 1480 N ASN 190 1.899 50.0308.729 1481 CA ASN 190 1.862 50.684 7.452 1482 CB ASN 190 0.476 50.6866.779 1483 CG ASN 190 0.332 49.449 5.902 1484 OD1 ASN 190 −0.330 48.4876.286 1485 ND2 ASN 190 0.992 49.463 4.715 1486 C ASN 190 2.181 52.1167.730 1487 O ASN 190 1.663 52.693 8.686 1488 N ARG 191 3.050 52.7296.905 1489 CA ARG 191 3.341 54.108 7.114 1490 CB ARG 191 4.743 54.5016.630 1491 CG ARG 191 5.838 53.910 7.532 1492 CD ARG 191 7.253 54.0886.981 1493 NE ARG 191 8.195 54.110 8.135 1494 CZ ARG 191 9.463 54.5887.965 1495 NH1 ARG 191 9.860 55.036 6.735 1496 NH2 ARG 191 10.328 54.6309.002 1497 C ARG 191 2.291 54.868 6.382 1498 O ARG 191 1.161 54.3946.291 1499 N SER 192 2.632 56.080 5.869 1500 CA SER 192 1.622 56.9185.270 1501 CB SER 192 0.941 57.867 6.252 1502 OG SER 192 1.937 58.7076.805 1503 C SER 192 2.237 57.790 4.221 1504 O SER 192 3.327 57.5203.729 1505 N ASP 193 1.503 58.867 3.851 1506 CA ASP 193 1.844 59.6872.729 1507 CB ASP 193 0.617 60.136 1.928 1508 CG ASP 193 −0.214 61.0332.831 1509 OD1 ASP 193 −0.284 62.253 2.537 1510 OD2 ASP 193 −0.79560.522 3.825 1511 C ASP 193 2.568 60.911 3.194 1512 O ASP 193 2.38461.423 4.305 1513 N PRO 194 3.442 61.342 2.326 1514 CA PRO 194 4.64561.952 2.807 1515 CD PRO 194 3.655 60.565 1.122 1516 CB PRO 194 5.79861.242 2.093 1517 CG PRO 194 5.148 60.213 1.137 1518 C PRO 194 4.59363.407 2.499 1519 O PRO 194 5.478 63.909 1.817 1520 N VAL 195 3.53964.092 2.989 1521 CA VAL 195 3.218 65.438 2.618 1522 CB VAL 195 1.94065.890 3.271 1523 CG1 VAL 195 0.839 64.901 2.911 1524 CG2 VAL 195 2.16265.900 4.796 1525 C VAL 195 4.330 66.337 3.070 1526 O VAL 195 4.81066.200 4.197 1527 N THR 196 4.801 67.269 2.215 1528 CA THR 196 5.90968.104 2.619 1529 CB THR 196 6.932 68.383 1.561 1530 OG1 THR 196 6.97269.779 1.301 1531 CG2 THR 196 6.555 67.623 0.283 1532 C THR 196 5.37469.438 2.998 1533 O THR 196 4.428 69.942 2.388 1534 N LEU 197 5.97670.066 4.022 1535 CA LEU 197 5.496 71.369 4.332 1536 CB LEU 197 4.84671.506 5.710 1537 CG LEU 197 4.012 72.792 5.784 1538 CD2 LEU 197 4.69373.850 6.659 1539 CD1 LEU 197 2.563 72.498 6.188 1540 C LEU 197 6.64472.311 4.311 1541 O LEU 197 7.580 72.197 5.103 1542 N ASN 198 6.58873.290 3.396 1543 CA ASN 198 7.564 74.322 3.446 1544 CB ASN 198 8.46674.356 2.219 1545 CG ASN 198 8.878 72.904 2.012 1546 OD1 ASN 198 9.50772.312 2.888 1547 ND2 ASN 198 8.484 72.316 0.852 1548 C ASN 198 6.82175.601 3.534 1549 O ASN 198 5.792 75.813 2.912 1550 N VAL 199 7.33376.495 4.374 1551 CA VAL 199 6.557 77.613 4.778 1552 CB VAL 199 6.84077.858 6.242 1553 CG1 VAL 199 8.193 77.219 6.573 1554 CG2 VAL 199 6.81379.351 6.565 1555 C VAL 199 6.973 78.774 3.908 1556 O VAL 199 7.99078.707 3.214 1557 N THR 200 6.185 79.870 3.900 1558 CA THR 200 6.72881.171 3.623 1559 CB THR 200 6.094 81.916 2.481 1560 OG1 THR 200 6.22781.169 1.276 1561 CG2 THR 200 6.776 83.288 2.348 1562 C THR 200 6.33781.976 4.804 1563 O THR 200 5.256 81.771 5.355 1564 N TYR 201 7.19382.910 5.249 1565 CA TYR 201 6.792 83.623 6.413 1566 CB TYR 201 7.89783.850 7.454 1567 CG TYR 201 9.306 83.647 6.952 1568 CD1 TYR 201 9.75884.189 5.769 1569 CD2 TYR 201 10.212 82.922 7.709 1570 CE1 TYR 20111.054 83.995 5.352 1571 CE2 TYR 201 11.509 82.728 7.291 1572 CZ TYR 20111.937 83.265 6.108 1573 OH TYR 201 13.266 83.069 5.669 1574 C TYR 2016.237 84.945 6.007 1575 O TYR 201 6.022 85.205 4.824 1576 N GLY 2025.958 85.815 6.996 1577 CA GLY 202 5.526 87.138 6.678 1578 C GLY 2026.519 88.088 7.275 1579 O GLY 202 6.408 88.501 8.426 1580 N PRO 2037.540 88.402 6.524 1581 CA PRO 203 8.742 88.910 7.125 1582 CD PRO 2037.826 87.571 5.373 1583 CB PRO 203 9.927 88.292 6.401 1584 CG PRO 2039.325 87.222 5.468 1585 C PRO 203 8.814 90.394 7.014 1586 O PRO 2037.777 91.011 6.660 1587 OXT PRO 203 9.914 90.948 7.270

[0139] TABLE 5 Full coordinate set of D1 of human CEACAM1a (homologymodel) ANum AType RType RNum X Y Z 1 N GLN 1 7.864 28.910 40.421 2 CAGLN 1 7.905 27.435 40.349 3 CB GLN 1 6.753 26.828 41.151 4 CG GLN 15.434 27.551 40.885 5 CD GLN 1 4.357 26.911 41.737 6 OE1 GLN 1 4.47825.734 42.076 7 NE2 GLN 1 3.289 27.681 42.089 8 C GLN 1 7.774 26.95838.948 9 O GLN 1 6.836 26.227 38.632 10 N LEU 2 8.764 27.359 38.125 11CA LEU 2 9.167 26.717 36.915 12 CB LEU 2 10.129 25.553 37.221 13 CG LEU2 10.535 24.698 36.012 14 CD2 LEU 2 10.824 23.248 36.438 15 CD1 LEU 211.682 25.358 35.232 16 C LEU 2 7.991 26.166 36.179 17 O LEU 2 7.73624.967 36.238 18 N THR 3 7.241 26.998 35.441 19 CA THR 3 6.453 26.34134.443 20 CB THR 3 4.973 26.259 34.701 21 OG1 THR 3 4.432 27.544 34.94222 CG2 THR 3 4.743 25.336 35.894 23 C THR 3 6.588 27.073 33.167 24 O THR3 7.667 27.522 32.778 25 N THR 4 5.420 27.156 32.515 26 CA THR 4 5.11127.326 31.137 27 CB THR 4 3.616 27.502 30.981 28 OG1 THR 4 3.185 27.17329.674 29 CG2 THR 4 3.223 28.944 31.374 30 C THR 4 5.773 28.512 30.53931 O THR 4 6.732 29.098 31.036 32 N GLU 5 5.210 28.861 29.388 33 CA GLU5 5.379 30.103 28.756 34 CB GLU 5 6.812 30.238 28.196 35 CG GLU 5 7.10731.576 27.539 36 CD GLU 5 7.502 31.227 26.125 37 OE1 GLU 5 8.006 30.08925.948 38 OE2 GLU 5 7.331 32.073 25.204 39 C GLU 5 4.370 30.001 27.66840 O GLU 5 3.400 29.254 27.790 41 N SER 6 4.565 30.735 26.572 42 CA SER6 3.788 30.481 25.404 43 CB SER 6 2.282 30.723 25.535 44 OG SER 6 1.65930.546 24.275 45 C SER 6 4.290 31.419 24.394 46 O SER 6 4.782 32.49624.709 47 N MET 7 4.215 30.996 23.130 48 CA MET 7 4.890 31.715 22.101 49CB MET 7 6.336 31.193 21.948 50 CG MET 7 7.139 31.798 20.802 51 SD MET 78.319 30.656 20.026 52 CE MET 7 7.826 31.072 18.330 53 C MET 7 4.13831.429 20.842 54 O MET 7 3.482 30.398 20.737 55 N PRO 8 4.189 32.26519.855 56 CA PRO 8 4.884 33.515 19.894 57 CD PRO 8 3.895 31.801 18.51658 CB PRO 8 5.090 33.925 18.433 59 CG PRO 8 4.756 32.670 17.598 60 C PRO8 4.045 34.483 20.658 61 O PRO 8 2.848 34.548 20.391 62 N PHE 9 4.62035.255 21.599 63 CA PHE 9 3.770 36.228 22.220 64 CB PHE 9 4.400 36.99423.388 65 CG PHE 9 5.847 36.673 23.378 66 CD1 PHE 9 6.745 37.489 22.72767 CD2 PHE 9 6.287 35.541 24.022 68 CE1 PHE 9 8.083 37.176 22.710 69 CE2PHE 9 7.622 35.226 24.008 70 CZ PHE 9 8.516 36.047 23.364 71 C PHE 93.426 37.232 21.189 72 O PHE 9 4.245 37.567 20.341 73 N ASN 10 2.18537.730 21.242 74 CA ASN 10 1.677 38.584 20.230 75 CB ASN 10 2.602 39.76419.931 76 CG ASN 10 2.550 40.570 21.214 77 OD1 ASN 10 3.547 40.85221.877 78 ND2 ASN 10 1.301 40.930 21.603 79 C ASN 10 1.441 37.750 19.03480 O ASN 10 2.355 37.147 18.472 81 N VAL 11 0.161 37.663 18.650 82 CAVAL 11 −0.206 36.723 17.646 83 CB VAL 11 −0.991 35.584 18.211 84 CG1 VAL11 −1.030 34.470 17.161 85 CG2 VAL 11 −0.352 35.193 19.558 86 C VAL 11−1.051 37.448 16.661 87 O VAL 11 −1.866 38.291 17.030 88 N ALA 12 −0.86837.137 15.370 89 CA ALA 12 −1.622 37.830 14.377 90 CB ALA 12 −0.87537.972 13.044 91 C ALA 12 −2.843 37.032 14.103 92 O ALA 12 −3.216 36.14514.868 93 N GLU 13 −3.500 37.353 12.978 94 CA GLU 13 −4.686 36.65812.606 95 CB GLU 13 −5.779 37.609 12.095 96 CG GLU 13 −7.169 36.98612.079 97 CD GLU 13 −8.148 38.066 11.674 98 OE1 GLU 13 −8.617 38.80612.570 99 OE2 GLU 13 −8.432 38.156 10.444 100 C GLU 13 −4.316 35.74211.488 101 O GLU 13 −3.530 36.101 10.613 102 N GLY 14 −4.870 34.51711.494 103 CA GLY 14 −4.533 33.571 10.470 104 C GLY 14 −3.205 32.98610.822 105 O GLY 14 −2.596 32.257 10.036 106 N LYS 15 −2.707 33.28612.029 107 CA LYS 15 −1.453 32.689 12.359 108 CB LYS 15 −0.349 33.72612.590 109 CG LYS 15 −0.292 34.675 11.389 110 CD LYS 15 0.965 35.54011.278 111 CE LYS 15 1.879 35.141 10.120 112 NZ LYS 15 2.884 34.18510.621 113 C LYS 15 −1.661 31.854 13.575 114 O LYS 15 −2.580 32.07314.362 115 N GLU 16 −0.802 30.831 13.721 116 CA GLU 16 −0.926 29.89714.790 117 CB GLU 16 −0.251 28.537 14.518 118 CG GLU 16 −0.977 27.60413.550 119 CD GLU 16 −0.103 26.370 13.360 120 OE1 GLU 16 −0.591 25.24413.655 121 OE2 GLU 16 1.065 26.539 12.922 122 C GLU 16 −0.175 30.45115.949 123 O GLU 16 0.317 31.576 15.925 124 N VAL 17 −0.075 29.61616.999 125 CA VAL 17 0.741 29.857 18.148 126 CB VAL 17 0.029 30.57019.253 127 CG1 VAL 17 0.911 31.725 19.758 128 CG2 VAL 17 −1.369 30.97618.751 129 C VAL 17 1.022 28.498 18.678 130 O VAL 17 0.383 27.518 18.292131 N LEU 18 1.994 28.395 19.595 132 CA LEU 18 2.164 27.154 20.279 133CB LEU 18 3.505 26.441 20.019 134 CG LEU 18 3.850 25.424 21.125 135 CD2LEU 18 5.320 24.977 21.043 136 CD1 LEU 18 2.880 24.239 21.133 137 C LEU18 2.153 27.470 21.729 138 O LEU 18 2.567 28.543 22.164 139 N LEU 191.669 26.538 22.544 140 CA LEU 19 1.728 26.881 23.921 141 CB LEU 190.394 26.658 24.638 142 CG LEU 19 −0.596 27.812 24.336 143 CD2 LEU 19−0.441 28.370 22.911 144 CD1 LEU 19 −0.515 28.889 25.420 145 C LEU 192.807 26.039 24.486 146 O LEU 19 2.816 24.823 24.273 147 N LEU 20 3.78226.676 25.164 148 CA LEU 20 4.987 25.975 25.493 149 CB LEU 20 6.25726.774 25.149 150 CG LEU 20 7.502 25.954 24.741 151 CD2 LEU 20 8.77826.814 24.806 152 CD1 LEU 20 7.325 25.298 23.361 153 C LEU 20 5.00525.775 26.962 154 O LEU 20 5.196 26.733 27.710 155 N VAL 21 4.849 24.52227.421 156 CA VAL 21 5.225 24.294 28.779 157 CB VAL 21 4.501 23.16329.456 158 CG1 VAL 21 5.442 22.475 30.460 159 CG2 VAL 21 3.238 23.73230.128 160 C VAL 21 6.659 23.936 28.702 161 O VAL 21 7.094 23.345 27.718162 N HIS 22 7.440 24.321 29.724 163 CA HIS 22 8.823 23.981 29.717 164ND1 HIS 22 9.299 26.554 28.400 165 CG HIS 22 9.553 26.362 29.736 166 CBHIS 22 9.708 25.030 30.376 167 NE2 HIS 22 9.413 28.575 29.329 168 CD2HIS 22 9.615 27.608 30.293 169 CE1 HIS 22 9.225 27.902 28.213 170 C HIS22 8.950 22.776 30.545 171 O HIS 22 8.376 21.730 30.252 172 N ASN 239.726 22.917 31.629 173 CA ASN 23 9.999 21.795 32.469 174 CB ASN 2311.184 22.041 33.404 175 CG ASN 23 12.345 22.422 32.510 176 OD1 ASN 2312.358 23.495 31.910 177 ND2 ASN 23 13.342 21.506 32.397 178 C ASN 238.798 21.519 33.309 179 O ASN 23 8.119 22.429 33.783 180 N LEU 24 8.53320.220 33.520 181 CA LEU 24 7.437 19.792 34.321 182 CB LEU 24 7.25720.563 35.639 183 CG LEU 24 8.459 20.481 36.608 184 CD2 LEU 24 9.12819.098 36.619 185 CD1 LEU 24 8.029 20.931 38.015 186 C LEU 24 6.18019.899 33.533 187 O LEU 24 5.892 20.985 33.036 188 N PRO 25 5.385 18.86933.334 189 CA PRO 25 5.765 17.486 33.483 190 CD PRO 25 4.755 18.98332.033 191 CB PRO 25 6.453 17.210 32.152 192 CG PRO 25 5.522 17.96031.154 193 C PRO 25 6.355 16.855 34.722 194 O PRO 25 6.991 17.492 35.556195 N GLN 26 6.121 15.540 34.878 196 CA GLN 26 6.673 14.829 35.990 197CB GLN 26 6.524 15.517 37.362 198 CG GLN 26 7.565 15.034 38.374 199 CDGLN 26 7.638 15.999 39.545 200 OE1 GLN 26 8.010 15.552 40.627 201 NE2GLN 26 7.269 17.297 39.361 202 C GLN 26 5.880 13.591 36.126 203 O GLN 265.004 13.565 36.990 204 N GLN 27 6.199 12.575 35.283 205 CA GLN 27 5.73811.207 35.329 206 CB GLN 27 6.639 10.313 36.200 207 CG GLN 27 7.0828.995 35.562 208 CD GLN 27 7.740 8.199 36.684 209 OE1 GLN 27 8.019 7.00336.595 210 NE2 GLN 27 8.019 8.921 37.796 211 C GLN 27 4.369 11.18435.907 212 O GLN 27 4.138 10.639 36.986 213 N LEU 28 3.446 11.879 35.222214 CA LEU 28 2.207 12.259 35.819 215 CB LEU 28 1.595 13.501 35.178 216CG LEU 28 2.209 14.829 35.660 217 CD2 LEU 28 1.667 15.253 37.044 218 CD1LEU 28 2.040 15.902 34.579 219 C LEU 28 1.235 11.156 35.616 220 O LEU 281.476 10.003 35.978 221 N PHE 29 0.076 11.517 35.050 222 CA PHE 29−0.946 10.546 34.866 223 CB PHE 29 −1.819 10.352 36.113 224 CG PHE 29−2.929 9.502 35.647 225 CD1 PHE 29 −2.770 8.146 35.488 226 CD2 PHE 29−4.149 10.063 35.354 227 CE1 PHE 29 −3.816 7.373 35.037 228 CE2 PHE 29−5.193 9.289 34.902 229 CZ PHE 29 −5.034 7.937 34.751 230 C PHE 29−1.842 11.097 33.810 231 O PHE 29 −2.267 10.395 32.893 232 N GLY 30−2.157 12.397 33.926 233 CA GLY 30 −3.108 12.964 33.035 234 C GLY 30−2.823 14.417 32.951 235 O GLY 30 −2.343 15.042 33.899 236 N TYR 31−3.109 14.990 31.769 237 CA TYR 31 −2.948 16.399 31.563 238 CB TYR 31−1.879 16.853 30.536 239 CG TYR 31 −0.785 15.892 30.141 240 CDI TYR 310.114 16.363 29.218 241 CD2 TYR 31 −0.616 14.590 30.578 242 CE1 TYR 311.170 15.607 28.781 243 CE2 TYR 31 0.429 13.817 30.153 244 CZ TYR 311.304 14.317 29.228 245 OH TYR 31 2.374 13.527 28.779 246 C TYR 31−4.246 16.838 30.972 247 O TYR 31 −4.993 16.012 30.454 248 N SER 32−4.566 18.144 31.017 249 CA SER 32 −5.727 18.548 30.281 250 CB SER 32−7.049 18.081 30.909 251 OG SER 32 −8.157 18.657 30.240 252 C SER 32−5.755 20.038 30.208 253 O SER 32 −5.827 20.731 31.222 254 N TRP 33−5.704 20.543 28.965 255 CA TRP 33 −5.728 21.934 28.654 256 CB TRP 33−5.426 22.186 27.174 257 CG TRP 33 −3.994 22.565 27.034 258 CD2 TRP 33−3.532 23.884 26.685 259 CD1 TRP 33 −2.897 21.810 27.279 260 NE1 TRP 33−1.763 22.570 27.138 261 CE2 TRP 33 −2.140 23.838 26.781 262 CE3 TRP 33−4.207 25.020 26.335 263 CZ2 TRP 33 −1.390 24.952 26.526 264 CZ3 TRP 33−3.449 26.139 26.070 265 CH2 TRP 33 −2.074 26.091 26.167 266 C TRP 33−7.091 22.467 28.882 267 O TRP 33 −8.072 21.890 28.419 268 N TYR 34−7.213 23.612 29.572 269 CA TYR 34 −8.535 24.143 29.605 270 CB TYR 34−9.078 24.365 31.014 271 CG TYR 34 −9.277 23.022 31.635 272 CD1 TYR 34−8.355 22.560 32.548 273 CD2 TYR 34 −10.358 22.221 31.325 274 CE1 TYR 34−8.519 21.335 33.154 275 CE2 TYR 34 −10.511 21.001 31.937 276 CZ TYR 34−9.592 20.542 32.850 277 OH TYR 34 −9.748 19.291 33.481 278 C TYR 34−8.539 25.445 28.888 279 O TYR 34 −7.941 25.591 27.823 280 N LYS 35−9.271 26.420 29.453 281 CA LYS 35 −9.443 27.644 28.748 282 CB LYS 35−10.250 27.484 27.450 283 CG LYS 35 −10.468 28.818 26.736 284 CD LYS 35−11.374 28.723 25.508 285 CE LYS 35 −11.104 29.833 24.497 286 NZ LYS 35−12.067 29.747 23.377 287 C LYS 35 −10.221 28.566 29.618 288 O LYS 35−11.430 28.425 29.782 289 N GLY 36 −9.545 29.571 30.188 290 CA GLY 36−10.307 30.640 30.746 291 C GLY 36 −10.464 30.414 32.206 292 O GLY 36−11.476 30.805 32.776 293 N GLU 37 −9.441 29.820 32.849 294 CA GLU 37−9.358 29.835 34.276 295 CB GLU 37 −9.751 31.189 34.878 296 CG GLU 37−9.537 31.227 36.391 297 CD GLU 37 −9.866 32.621 36.886 298 OE1 GLU 37−9.523 32.930 38.062 299 OE2 GLU 37 −10.466 33.388 36.095 300 C GLU 37−10.260 28.798 34.845 301 O GLU 37 −9.885 28.108 35.792 302 N ARG 38−11.476 28.685 34.289 303 CA ARG 38 −12.476 27.817 34.819 304 CB ARG 38−13.715 27.734 33.930 305 CG ARG 38 −14.958 27.259 34.682 306 CD ARG 38−16.263 27.630 33.973 307 NE ARG 38 −17.327 27.672 35.021 308 CZ ARG 38−18.516 27.052 34.820 309 NH1 ARG 38 −19.463 27.008 35.806 310 NH2 ARG38 −18.765 26.449 33.622 311 C ARG 38 −11.872 26.467 34.897 312 O ARG 38−11.333 25.948 33.923 313 N VAL 39 −11.882 25.888 36.100 314 CA VAL 39−11.120 24.701 36.271 315 CB VAL 39 −10.699 24.551 37.692 316 CG1 VAL 39−9.955 23.230 37.882 317 CG2 VAL 39 −9.817 25.764 38.024 318 C VAL 39−11.985 23.564 35.839 319 O VAL 39 −11.559 22.408 35.824 320 N ASP 40−13.234 23.896 35.446 321 CA ASP 40 −14.169 22.938 34.931 322 CB ASP 40−15.544 23.568 34.582 323 CG ASP 40 −16.715 22.854 35.263 324 OD1 ASP 40−17.870 23.228 34.931 325 OD2 ASP 40 −16.475 21.952 36.115 326 C ASP 40−13.627 22.404 33.646 327 O ASP 40 −12.705 22.948 33.038 328 N GLY 41−14.234 21.295 33.193 329 CA GLY 41 −14.027 20.807 31.864 330 C GLY 41−15.369 20.822 31.213 331 O GLY 41 −15.604 20.069 30.263 332 N ASN 42−16.274 21.686 31.746 333 CA ASN 42 −17.482 22.111 31.081 334 CB ASN 42−17.890 23.507 31.578 335 CG ASN 42 −19.322 23.849 31.191 336 OD1 ASN 42−19.600 24.338 30.100 337 ND2 ASN 42 −20.261 23.621 32.147 338 C ASN 42−17.057 22.257 29.663 339 O ASN 42 −17.528 21.564 28.759 340 N ARG 43−16.022 23.093 29.504 341 CA ARG 43 −15.131 22.973 28.409 342 CB ARG 43−14.937 24.311 27.668 343 CG ARG 43 −16.017 24.489 26.605 344 CD ARG 43−16.642 23.129 26.298 345 NE ARG 43 −17.709 23.312 25.290 346 CZ ARG 43−18.952 22.811 25.558 347 NH1 ARG 43 −19.891 22.784 24.578 348 NH2 ARG43 −19.223 22.316 26.802 349 C ARG 43 −13.813 22.513 28.969 350 O ARG 43−12.994 23.317 29.415 351 N GLN 44 −13.594 21.177 28.946 352 CA GLN 44−12.271 20.637 29.087 353 CB GLN 44 −12.243 19.210 29.676 354 CG GLN 44−10.918 18.467 29.447 355 CD GLN 44 −10.916 17.123 30.179 356 OE1 GLN 44−11.231 17.025 31.365 357 NE2 GLN 44 −10.551 16.049 29.436 358 C GLN 44−11.743 20.550 27.695 359 O GLN 44 −12.522 20.495 26.743 360 N ILE 45−10.411 20.568 27.512 361 CA ILE 45 −9.980 20.694 26.151 362 CB ILE 45−9.246 21.989 25.891 363 CG2 ILE 45 −9.076 22.147 24.372 364 CG1 ILE 45−10.019 23.175 26.515 365 CD1 ILE 45 −10.808 24.010 25.500 366 C ILE 45−9.138 19.504 25.767 367 O ILE 45 −9.641 18.593 25.117 368 N VAL 46−7.840 19.462 26.143 369 CA VAL 46 −6.992 18.393 25.668 370 CB VAL 46−5.594 18.872 25.311 371 CG1 VAL 46 −4.592 17.731 25.039 372 CG2 VAL 46−5.768 19.765 24.079 373 C VAL 46 −6.962 17.335 26.729 374 O VAL 46−7.408 17.567 27.854 375 N GLY 47 −6.447 16.130 26.390 376 CA GLY 47−6.256 15.083 27.349 377 C GLY 47 −5.195 14.151 26.843 378 O GLY 47−5.408 12.942 26.782 379 N TYR 48 −4.000 14.678 26.500 380 CA TYR 48−2.917 13.746 26.434 381 CB TYR 48 −1.531 14.310 26.042 382 CG TYR 48−0.622 13.147 25.751 383 CD1 TYR 48 0.323 12.732 26.663 384 CD2 TYR 48−0.694 12.460 24.563 385 CE1 TYR 48 1.156 11.669 26.392 386 CE2 TYR 480.131 11.397 24.281 387 CZ TYR 48 1.053 10.986 25.202 388 OH TYR 481.901 9.897 24.924 389 C TYR 48 −2.840 13.221 27.824 390 O TYR 48 −3.09813.941 28.788 391 N ALA 49 −2.567 11.917 27.937 392 CA ALA 49 −2.59711.247 29.188 393 CB ALA 49 −3.492 9.982 29.140 394 C ALA 49 −1.20310.792 29.376 395 O ALA 49 −0.412 10.810 28.434 396 N ILE 50 −0.81410.372 30.585 397 CA ILE 50 0.504 9.811 30.495 398 CB ILE 50 1.51710.327 31.511 399 CG2 ILE 50 2.410 9.159 31.969 400 CG1 ILE 50 2.30811.475 30.856 401 CD1 ILE 50 3.793 11.480 31.193 402 C ILE 50 0.3328.337 30.609 403 O ILE 50 −0.025 7.817 31.665 404 N GLY 51 0.586 7.63729.476 405 CA GLY 51 0.297 6.232 29.393 406 C GLY 51 −0.504 6.047 28.152407 O GLY 51 −0.185 6.714 27.171 408 N THR 52 −1.523 5.147 28.200 409 CATHR 52 −2.381 4.973 27.085 410 CB THR 52 −3.635 4.167 27.336 411 OG1 THR52 −4.810 4.863 26.951 412 CG2 THR 52 −3.760 3.813 28.806 413 C THR 52−2.779 6.302 26.621 414 O THR 52 −3.542 7.031 27.248 415 N GLN 53 −2.1906.667 25.463 416 CA GLN 53 −3.009 7.112 24.409 417 CB GLN 53 −4.4236.548 24.578 418 CG GLN 53 −5.048 5.889 23.362 419 CD GLN 53 −6.5246.039 23.665 420 OE1 GLN 53 −7.042 7.143 23.518 421 NE2 GLN 53 −7.2034.942 24.100 422 C GLN 53 −3.072 8.574 24.470 423 O GLN 53 −2.479 9.19825.349 424 N GLN 54 −3.819 9.214 23.551 425 CA GLN 54 −4.156 10.52123.975 426 CB GLN 54 −3.252 11.642 23.403 427 CG GLN 54 −3.871 12.79322.614 428 CD GLN 54 −3.905 12.285 21.192 429 OE1 GLN 54 −3.098 12.62620.326 430 NE2 GLN 54 −4.883 11.374 20.961 431 C GLN 54 −5.601 10.69323.713 432 O GLN 54 −6.296 9.749 23.322 433 N ALA 55 −6.150 11.87724.008 434 CA ALA 55 −7.527 11.778 24.293 435 CB ALA 55 −7.792 11.76425.802 436 C ALA 55 −8.217 12.955 23.720 437 O ALA 55 −7.598 13.87523.178 438 N THR 56 −9.560 12.958 23.823 439 CA THR 56 −10.167 14.13023.308 440 CB THR 56 −10.183 14.184 21.820 441 OG1 THR 56 −10.707 15.43721.408 442 CG2 THR 56 −11.049 13.030 21.273 443 C THR 56 −11.576 14.28623.787 444 O THR 56 −12.456 13.440 23.640 445 N PRO 57 −11.721 15.44324.365 446 CA PRO 57 −12.957 15.888 24.950 447 CD PRO 57 −10.565 15.85425.144 448 CB PRO 57 −12.611 16.580 26.261 449 CG PRO 57 −11.140 16.22326.521 450 C PRO 57 −13.739 16.844 24.112 451 O PRO 57 −13.824 16.68922.893 452 N GLY 58 −14.324 17.848 24.798 453 CA GLY 58 −15.723 18.19824.742 454 C GLY 58 −16.049 19.198 23.669 455 O GLY 58 −17.098 19.05723.036 456 N PRO 59 −15.284 20.228 23.404 457 CA PRO 59 −15.832 21.29422.633 458 CD PRO 59 −14.141 20.654 24.194 459 CB PRO 59 −15.133 22.57823.069 460 CG PRO 59 −14.139 22.182 24.173 461 C PRO 59 −15.508 21.06421.206 462 O PRO 59 −15.815 20.009 20.655 463 N ALA 60 −14.861 22.08020.609 464 CA ALA 60 −14.428 22.067 19.250 465 CB ALA 60 −14.415 23.47118.628 466 C ALA 60 −13.021 21.586 19.235 467 O ALA 60 −12.244 21.86120.146 468 N ASN 61 −12.644 20.869 18.164 469 CA ASN 61 −11.253 20.59917.925 470 CB ASN 61 −10.939 19.086 17.858 471 CG ASN 61 −9.497 18.76818.254 472 OD1 ASN 61 −9.153 17.589 18.324 473 ND2 ASN 61 −8.641 19.79218.499 474 C ASN 61 −10.974 21.179 16.580 475 O ASN 61 −10.469 20.49715.689 476 N SER 62 −11.327 22.463 16.386 477 CA SER 62 −11.251 22.99015.058 478 CB SER 62 −11.807 24.411 14.932 479 OG SER 62 −13.209 24.34114.753 480 C SER 62 −9.814 23.054 14.720 481 O SER 62 −9.406 22.87013.574 482 N GLY 63 −8.991 23.332 15.732 483 CA GLY 63 −7.618 23.51815.427 484 C GLY 63 −6.936 23.862 16.694 485 O GLY 63 −6.701 25.02117.027 486 N ARG 64 −6.619 22.796 17.430 487 CA ARG 64 −5.777 22.82718.571 488 CB ARG 64 −6.569 22.796 19.899 489 CG ARG 64 −7.288 24.10720.232 490 CD ARG 64 −8.778 24.128 19.890 491 NE ARG 64 −9.200 25.55919.923 492 CZ ARG 64 −9.728 26.090 21.066 493 NH1 ARG 64 −10.073 27.41521.086 494 NH2 ARG 64 −9.917 25.310 22.171 495 C ARG 64 −5.039 21.55018.429 496 O ARG 64 −5.392 20.716 17.593 497 N GLU 65 −3.987 21.36119.217 498 CA GLU 65 −3.408 20.062 19.192 499 CB GLU 65 −2.457 19.82618.018 500 CG GLU 65 −2.927 18.721 17.072 501 CD GLU 65 −2.859 19.30615.683 502 OE1 GLU 65 −2.116 18.744 14.828 503 OE2 GLU 65 −3.527 20.34815.474 504 C GLU 65 −2.565 19.997 20.389 505 O GLU 65 −2.089 21.02020.869 506 N THR 66 −2.346 18.799 20.920 507 CA THR 66 −1.521 18.85622.070 508 CB THR 66 −2.105 18.180 23.279 509 OG1 THR 66 −1.538 18.69024.467 510 CG2 THR 66 −1.837 16.672 23.183 511 C THR 66 −0.231 18.20921.721 512 O THR 66 0.038 17.883 20.562 513 N ILE 67 0.621 18.013 22.733514 CA ILE 67 1.763 17.181 22.520 515 CB ILE 67 2.915 17.871 21.858 516CG2 ILE 67 3.484 18.900 22.853 517 CG1 ILE 67 3.946 16.833 21.377 518CD1 ILE 67 5.037 17.448 20.501 519 C ILE 67 2.233 16.752 23.863 520 OILE 67 1.867 17.356 24.868 521 N TYR 68 3.073 15.694 23.878 522 CA TYR68 3.688 15.102 25.034 523 CB TYR 68 4.947 14.266 24.647 524 CG TYR 685.363 13.318 25.725 525 CD1 TYR 68 4.425 12.517 26.336 526 CD2 TYR 686.686 13.209 26.112 527 CE1 TYR 68 4.804 11.631 27.319 528 CE2 TYR 687.056 12.323 27.092 529 CZ TYR 68 6.120 11.526 27.705 530 OH TYR 686.513 10.615 28.705 531 C TYR 68 4.038 16.178 26.029 532 O TYR 68 3.55016.140 27.158 533 N PRO 69 4.845 17.157 25.683 534 CA PRO 69 5.43618.039 26.660 535 CD PRO 69 5.568 17.173 24.418 536 CB PRO 69 6.49318.851 25.914 537 CG PRO 69 6.805 18.051 24.638 538 C PRO 69 4.45018.900 27.391 539 O PRO 69 4.886 19.739 28.175 540 N ASN 70 3.131 18.72727.175 541 CA ASN 70 2.173 19.562 27.845 542 CB ASN 70 2.411 19.69529.355 543 CG ASN 70 1.216 20.433 29.947 544 OD1 ASN 70 1.329 21.12030.963 545 ND2 ASN 70 0.032 20.262 29.302 546 C ASN 70 2.291 20.91327.232 547 O ASN 70 2.230 21.945 27.901 548 N ALA 71 2.478 20.914 25.908549 CA ALA 71 2.411 22.096 25.118 550 CB ALA 71 3.577 22.194 24.105 551C ALA 71 1.136 21.929 24.362 552 O ALA 71 0.758 20.806 24.031 553 N SER72 0.397 23.020 24.103 554 CA SER 72 −0.759 22.808 23.287 555 CB SER 72−2.104 23.047 23.968 556 OG SER 72 −3.068 23.427 23.000 557 C SER 72−0.681 23.757 22.152 558 O SER 72 −0.636 24.975 22.336 559 N LEU 73−0.663 23.206 20.934 560 CA LEU 73 −0.619 24.034 19.778 561 CB LEU 73−0.302 23.273 18.485 562 CG LEU 73 0.180 24.196 17.349 563 CD2 LEU 73−0.603 23.914 16.058 564 CD1 LEU 73 1.704 24.109 17.167 565 C LEU 73−1.973 24.628 19.624 566 O LEU 73 −2.900 24.322 20.371 567 N LEU 74−2.101 25.533 18.646 568 CA LEU 74 −3.345 26.199 18.447 569 CB LEU 74−3.459 27.536 19.199 570 CG LEU 74 −4.850 27.823 19.824 571 CD2 LEU 74−4.926 27.285 21.258 572 CD1 LEU 74 −5.997 27.327 18.932 573 C LEU 74−3.366 26.527 17.004 574 O LEU 74 −2.447 27.169 16.498 575 N ILE 75−4.402 26.085 16.280 576 CA ILE 75 −4.410 26.523 14.926 577 CB ILE 75−5.033 25.576 13.940 578 CG2 ILE 75 −6.560 25.787 13.924 579 CG1 ILE 75−4.371 25.786 12.569 580 CD1 ILE 75 −5.283 25.535 11.370 581 C ILE 75−5.209 27.774 14.920 582 O ILE 75 −5.634 28.219 15.986 583 N GLN 76−5.408 28.330 13.700 584 CA GLN 76 −6.311 29.379 13.310 585 CB GLN 76−7.406 28.875 12.367 586 CG GLN 76 −6.821 28.596 10.985 587 CD GLN 76−7.923 28.169 10.039 588 OE1 GLN 76 −7.629 27.449 9.087 589 NE2 GLN 76−9.191 28.592 10.298 590 C GLN 76 −6.893 30.066 14.492 591 O GLN 76−8.057 29.899 14.851 592 N ASN 77 −6.021 30.859 15.134 593 CA ASN 77−6.337 31.584 16.314 594 CB ASN 77 −5.184 32.526 16.704 595 CG ASN 77−5.119 32.678 18.220 596 OD1 ASN 77 −4.232 33.356 18.739 597 ND2 ASN 77−6.059 32.025 18.950 598 C ASN 77 −7.545 32.403 16.002 599 O ASN 77−8.675 31.980 16.235 600 N VAL 78 −7.315 33.611 15.450 601 CA VAL 78−8.355 34.583 15.265 602 CB VAL 78 −9.623 34.016 14.667 603 CG1 VAL 78−10.475 35.153 14.066 604 CG2 VAL 78 −9.226 32.975 13.609 605 C VAL 78−8.582 35.198 16.612 606 O VAL 78 −7.768 35.005 17.511 607 N THR 79−9.652 35.996 16.782 608 CA THR 79 −9.706 36.891 17.903 609 CB THR 79−10.289 38.205 17.499 610 OG1 THR 79 −10.382 39.062 18.620 611 CG2 THR79 −11.681 37.963 16.897 612 C THR 79 −10.580 36.309 18.960 613 O THR 79−10.677 36.823 20.073 614 N GLN 80 −11.246 35.210 18.606 615 CA GLN 80−12.325 34.683 19.364 616 CB GLN 80 −13.210 33.867 18.421 617 CG GLN 80−13.740 34.777 17.308 618 CD GLN 80 −14.815 35.642 17.953 619 OE1 GLN 80−14.729 36.866 18.055 620 NE2 GLN 80 −15.882 34.950 18.432 621 C GLN 80−11.754 33.838 20.457 622 O GLN 80 −12.408 33.580 21.467 623 N ASN 81−10.493 33.401 20.273 624 CA ASN 81 −9.845 32.514 21.195 625 CB ASN 81−9.062 31.416 20.476 626 CG ASN 81 −10.139 30.699 19.692 627 OD1 ASN 81−11.288 30.716 20.126 628 ND2 ASN 81 −9.784 30.076 18.540 629 C ASN 81−8.888 33.313 22.000 630 O ASN 81 −8.101 32.778 22.778 631 N ASP 82−8.968 34.644 21.836 632 CA ASP 82 −8.188 35.547 22.620 633 CB ASP 82−8.377 37.004 22.186 634 CG ASP 82 −7.340 37.818 22.921 635 OD1 ASP 82−7.545 39.054 23.060 636 OD2 ASP 82 −6.320 37.221 23.353 637 C ASP 82−8.618 35.414 24.044 638 O ASP 82 −9.805 35.230 24.308 639 N THR 83−7.631 35.499 24.967 640 CA THR 83 −7.744 35.293 26.390 641 CB THR 83−9.121 35.035 26.931 642 OG1 THR 83 −9.126 35.158 28.348 643 CG2 THR 83−9.552 33.618 26.534 644 C THR 83 −6.930 34.089 26.723 645 O THR 83−6.469 33.378 25.832 646 N GLY 84 −6.701 33.852 28.031 647 CA GLY 84−5.658 32.941 28.418 648 C GLY 84 −6.249 31.613 28.750 649 O GLY 84−7.366 31.524 29.253 650 N PHE 85 −5.479 30.539 28.478 651 CA PHE 85−5.972 29.202 28.621 652 CB PHE 85 −5.604 28.296 27.427 653 CG PHE 85−6.219 28.832 26.167 654 CD1 PHE 85 −5.787 30.011 25.592 655 CD2 PHE 85−7.246 28.150 25.546 656 CE1 PHE 85 −6.360 30.488 24.431 657 CE2 PHE 85−7.824 28.618 24.387 658 CZ PHE 85 −7.382 29.794 23.826 659 C PHE 85−5.407 28.626 29.891 660 O PHE 85 −5.385 29.278 30.935 661 N TYR 86−4.969 27.353 29.843 662 CA TYR 86 −4.667 26.675 31.075 663 CB TYR 86−5.923 26.733 31.984 664 CG TYR 86 −6.011 25.980 33.293 665 CD1 TYR 86−5.095 26.014 34.332 666 CD2 TYR 86 −7.149 25.235 33.478 667 CE1 TYR 86−5.326 25.310 35.501 668 CE2 TYR 86 −7.407 24.534 34.632 669 CZ TYR 86−6.480 24.563 35.639 670 OH TYR 86 −6.739 23.847 36.821 671 C TYR 86−4.286 25.273 30.709 672 O TYR 86 −4.093 24.950 29.535 673 N THR 87−4.144 24.422 31.742 674 CA THR 87 −4.055 23.003 31.594 675 CB THR 87−2.937 22.504 30.693 676 OG1 THR 87 −2.910 21.082 30.685 677 CG2 THR 87−1.579 23.062 31.154 678 C THR 87 −3.852 22.466 32.974 679 O THR 87−2.848 22.730 33.637 680 N LEU 88 −4.869 21.729 33.434 681 CA LEU 88−4.907 21.063 34.699 682 CB LEU 88 −6.356 20.641 34.985 683 CG LEU 88−6.629 19.766 36.207 684 CD2 LEU 88 −8.135 19.446 36.308 685 CD1 LEU 88−6.050 20.422 37.460 686 C LEU 88 −4.079 19.843 34.501 687 O LEU 88−3.939 19.408 33.364 688 N GLN 89 −3.480 19.273 35.568 689 CA GLN 89−2.630 18.146 35.309 690 CB GLN 89 −1.151 18.547 35.126 691 CG GLN 89−0.868 19.538 33.992 692 CD GLN 89 0.327 20.378 34.436 693 OE1 GLN 890.234 21.601 34.534 694 NE2 GLN 89 1.469 19.701 34.727 695 C GLN 89−2.659 17.232 36.494 696 O GLN 89 −2.131 17.577 37.551 697 N VAL 90−3.253 16.028 36.340 698 CA VAL 90 −3.227 15.103 37.440 699 CB VAL 90−4.376 14.140 37.482 700 CG1 VAL 90 −3.865 12.873 38.190 701 CG2 VAL 90−5.609 14.815 38.136 702 C VAL 90 −2.000 14.226 37.378 703 O VAL 90−1.648 13.660 36.340 704 N ILE 91 −1.334 14.078 38.546 705 CA ILE 91−0.921 12.803 39.054 706 CB ILE 91 0.524 12.692 39.453 707 CG2 ILE 910.881 13.877 40.366 708 CG1 ILE 91 0.728 11.322 40.136 709 CD1 ILE 912.185 10.938 40.406 710 C ILE 91 −1.699 12.629 40.314 711 O ILE 91−1.933 13.584 41.052 712 N LYS 92 −2.115 11.386 40.586 713 CA LYS 92−3.063 11.114 41.614 714 CB LYS 92 −3.683 9.719 41.503 715 CG LYS 92−5.151 9.735 41.922 716 CD LYS 92 −5.717 11.156 42.035 717 CE LYS 92−6.775 11.299 43.126 718 NZ LYS 92 −8.109 10.930 42.598 719 C LYS 92−2.421 11.199 42.957 720 O LYS 92 −2.962 10.693 43.940 721 N SER 93−1.258 11.852 43.057 722 CA SER 93 −0.679 12.046 44.352 723 CB SER 930.859 12.047 44.311 724 OG SER 93 1.383 11.900 45.622 725 C SER 93−1.132 13.380 44.846 726 O SER 93 −1.555 13.539 45.990 727 N ASP 94−1.051 14.382 43.956 728 CA ASP 94 −1.608 15.672 44.224 729 CB ASP 94−0.575 16.691 44.750 730 CG ASP 94 −1.205 17.706 45.703 731 OD1 ASP 94−0.405 18.455 46.332 732 OD2 ASP 94 −2.456 17.765 45.819 733 C ASP 94−2.040 16.165 42.887 734 O ASP 94 −1.349 15.980 41.883 735 N LEU 95−3.207 16.821 42.832 736 CA LEU 95 −3.465 17.564 41.640 737 CB LEU 95−4.956 17.698 41.272 738 CG LEU 95 −5.228 18.471 39.972 739 CD2 LEU 95−6.660 19.026 39.965 740 CD1 LEU 95 −4.919 17.617 38.727 741 C LEU 95−2.931 18.932 41.906 742 O LEU 95 −3.032 19.430 43.025 743 N VAL 96−2.328 19.566 40.887 744 CA VAL 96 −1.663 20.827 41.038 745 CB VAL 96−0.249 20.733 40.543 746 CG1 VAL 96 0.601 21.885 41.093 747 CG2 VAL 960.293 19.354 40.967 748 C VAL 96 −2.427 21.778 40.179 749 O VAL 96−3.188 21.344 39.315 750 N ASN 97 −2.294 23.100 40.401 751 CA ASN 97−3.127 23.981 39.626 752 CB ASN 97 −3.747 25.163 40.423 753 CG ASN 97−5.012 25.706 39.736 754 OD1 ASN 97 −5.823 25.001 39.139 755 ND2 ASN 97−5.217 27.052 39.840 756 C ASN 97 −2.275 24.543 38.526 757 O ASN 97−2.143 23.926 37.469 758 N GLU 98 −1.699 25.737 38.785 759 CA GLU 98−1.191 26.735 37.874 760 CB GLU 98 −0.032 27.517 38.483 761 CG GLU 981.287 27.449 37.715 762 CD GLU 98 2.376 27.584 38.770 763 OE1 GLU 982.544 26.608 39.542 764 OE2 GLU 98 3.029 28.663 38.841 765 C GLU 98−0.728 26.203 36.554 766 O GLU 98 −0.161 25.113 36.461 767 N GLU 99−0.927 27.000 35.470 768 CA GLU 99 −0.181 28.221 35.246 769 CB GLU 991.008 27.997 34.285 770 CG GLU 99 0.769 28.478 32.847 771 CD GLU 990.534 27.310 31.874 772 OE1 GLU 99 0.403 27.603 30.646 773 OE2 GLU 990.520 26.130 32.315 774 C GLU 99 −1.113 29.184 34.536 775 O GLU 99−2.228 28.828 34.180 776 N ALA 100 −0.689 30.434 34.241 777 CA ALA 100−1.506 31.134 33.279 778 CB ALA 100 −2.228 32.374 33.847 779 C ALA 100−0.664 31.611 32.124 780 O ALA 100 0.328 32.307 32.331 781 N THR 101−1.048 31.277 30.872 782 CA THR 101 −0.412 31.900 29.731 783 CB THR 101−0.463 31.121 28.446 784 OG1 THR 101 −1.307 29.998 28.566 785 CG2 THR101 0.974 30.686 28.147 786 C THR 101 −1.164 33.152 29.494 787 O THR 101−1.616 33.761 30.452 788 N GLY 102 −1.319 33.601 28.238 789 CA GLY 102−2.072 34.817 28.094 790 C GLY 102 −1.556 35.545 26.912 791 O GLY 102−0.669 36.395 27.010 792 N GLN 103 −2.133 35.207 25.753 793 CA GLN 103−1.797 35.855 24.530 794 CB GLN 103 −1.573 34.860 23.381 795 CG GLN 103−2.554 33.681 23.462 796 CD GLN 103 −2.287 32.707 22.322 797 OE1 GLN 103−2.285 31.492 22.519 798 NE2 GLN 103 −2.009 33.259 21.109 799 C GLN 103−2.999 36.649 24.165 800 O GLN 103 −4.132 36.267 24.461 801 N PHE 104−2.773 37.790 23.493 802 CA PHE 104 −3.886 38.397 22.840 803 CB PHE 104−3.930 39.950 22.813 804 CG PHE 104 −3.357 40.565 24.038 805 CD1 PHE 104−3.696 40.119 25.298 806 CD2 PHE 104 −2.454 41.593 23.899 807 CE1 PHE104 −3.159 40.719 26.402 808 CE2 PHE 104 −1.915 42.198 25.000 809 CZ PHE104 −2.256 41.752 26.261 810 C PHE 104 −3.764 38.012 21.397 811 O PHE104 −2.999 37.126 21.014 812 N HIS 105 −4.542 38.716 20.566 813 CA HIS105 −4.634 38.545 19.149 814 ND1 HIS 105 −6.199 37.389 16.330 815 CG HIS105 −6.527 38.187 17.392 816 CB HIS 105 −6.034 37.991 18.798 817 NE2 HIS105 −7.632 38.891 15.559 818 CD2 HIS 105 −7.405 39.116 16.902 819 CE1HIS 105 −6.881 37.846 15.250 820 C HIS 105 −4.523 39.952 18.635 821 OHIS 105 −4.762 40.890 19.391 822 N VAL 106 −4.153 40.173 17.358 823 CAVAL 106 −4.310 41.516 16.872 824 CB VAL 106 −3.017 42.258 16.614 825 CG1VAL 106 −2.979 43.510 17.505 826 CG2 VAL 106 −1.826 41.317 16.876 827 CVAL 106 −5.103 41.439 15.602 828 O VAL 106 −5.483 40.356 15.159 829 NTYR 107 −5.392 42.613 14.997 830 CA TYR 107 −6.085 42.655 13.730 831 CBTYR 107 −7.458 43.370 13.780 832 CG TYR 107 −8.654 42.515 14.127 833 CD1TYR 107 −9.279 42.628 15.352 834 CD2 TYR 107 −9.203 41.622 13.229 835CE1 TYR 107 −10.390 41.874 15.659 836 CE2 TYR 107 −10.317 40.865 13.537837 CZ TYR 107 −10.930 40.985 14.762 838 OH TYR 107 −12.075 40.23115.113 839 C TYR 107 −5.239 43.461 12.772 840 O TYR 107 −4.918 44.62812.998 280 N LYS 35 −9.271 26.420 29.453 281 CA LYS 35 −9.443 27.64428.748 282 CB LYS 35 −10.250 27.484 27.450 283 CG LYS 35 −10.468 28.81826.736 284 CD LYS 35 −11.374 28.723 25.508 285 CE LYS 35 −11.104 29.83324.497 286 NZ LYS 35 −12.067 29.747 23.377 287 C LYS 35 −10.221 28.56629.618 288 O LYS 35 −11.430 28.425 29.782 289 N GLY 36 −9.545 29.57130.188 290 CA GLY 36 −10.307 30.640 30.746 291 C GLY 36 −10.464 30.41432.206 292 O GLY 36 −11.476 30.805 32.776 293 N GLU 37 −9.441 29.82032.849 294 CA GLU 37 −9.358 29.835 34.276 295 CB GLU 37 −9.751 31.18934.878 296 CG GLU 37 −9.537 31.227 36.391 297 CD GLU 37 −9.866 32.62136.886 298 OE1 GLU 37 −9.523 32.930 38.062 299 OE2 GLU 37 −10.466 33.38836.095 300 C GLU 37 −10.260 28.798 34.845 301 O GLU 37 −9.885 28.10835.792 302 N ARG 38 −11.476 28.685 34.289 303 CA ARG 38 −12.476 27.81734.819 304 CB ARG 38 −13.715 27.734 33.930 305 CG ARG 38 −14.958 27.25934.682 306 CD ARG 38 −16.263 27.630 33.973 307 NE ARG 38 −17.327 27.67235.021 308 CZ ARG 38 −18.516 27.052 34.820 309 NH1 ARG 38 −19.463 27.00835.806 310 NH2 ARG 38 −18.765 26.449 33.622 311 C ARG 38 −11.872 26.46734.897 312 O ARG 38 −11.333 25.948 33.923 313 N VAL 39 −11.882 25.88836.100 314 CA VAL 39 −11.120 24.701 36.271 315 CB VAL 39 −10.699 24.55137.692 316 CG1 VAL 39 −9.955 23.230 37.882 317 CG2 VAL 39 −9.817 25.76438.024 318 C VAL 39 −11.985 23.564 35.839 319 O VAL 39 −11.559 22.40835.824 320 N ASP 40 −13.234 23.896 35.446 321 CA ASP 40 −14.169 22.93834.931 322 CB ASP 40 −15.544 23.568 34.582 323 CG ASP 40 −16.715 22.85435.263 324 OD1 ASP 40 −17.870 23.228 34.931 325 OD2 ASP 40 −16.47521.952 36.115 326 C ASP 40 −13.627 22.404 33.646 327 O ASP 40 −12.70522.948 33.038 328 N GLY 41 −14.234 21.295 33.193 329 CA GLY 41 −14.02720.807 31.864 330 C GLY 41 −15.369 20.822 31.213 331 O GLY 41 −15.60420.069 30.263 332 N ASN 42 −16.274 21.686 31.746 333 CA ASN 42 −17.48222.111 31.081 334 CB ASN 42 −17.890 23.507 31.578 335 CG ASN 42 −19.32223.849 31.191 336 OD1 ASN 42 −19.600 24.338 30.100 337 ND2 ASN 42−20.261 23.621 32.147 338 C ASN 42 −17.057 22.257 29.663 339 O ASN 42−17.528 21.564 28.759 340 N ARG 43 −16.022 23.093 29.504 341 CA ARG 43−15.131 22.973 28.409 342 CB ARG 43 −14.937 24.311 27.668 343 CG ARG 43−16.017 24.489 26.605 344 CD ARG 43 −16.642 23.129 26.298 345 NE ARG 43−17.709 23.312 25.290 346 CZ ARG 43 −18.952 22.811 25.558 347 NH1 ARG 43−19.891 22.784 24.578 348 NH2 ARG 43 −19.223 22.316 26.802 349 C ARG 43−13.813 22.513 28.969 350 O ARG 43 −12.994 23.317 29.415 351 N GLN 44−13.594 21.177 28.946 352 CA GLN 44 −12.271 20.637 29.087 353 CB GLN 44−12.243 19.210 29.676 354 CG GLN 44 −10.918 18.467 29.447 355 CD GLN 44−10.916 17.123 30.179 356 OE1 GLN 44 −11.231 17.025 31.365 357 NE2 GLN44 −10.551 16.049 29.436 358 C GLN 44 −11.743 20.550 27.695 359 O GLN 44−12.522 20.495 26.743 360 N ILE 45 −10.411 20.568 27.512 361 CA ILE 45−9.980 20.694 26.151 362 CB ILE 45 −9.246 21.989 25.891 363 CG2 ILE 45−9.076 22.147 24.372 364 CG1 ILE 45 −10.019 23.175 26.515 365 CD1 ILE 45−10.808 24.010 25.500 366 C ILE 45 −9.138 19.504 25.767 367 O ILE 45−9.641 18.593 25.117

[0140] TABLE 6 Full coordinate set of D1D4 of murine CEACAM 1a (1691atoms, 419 amino acids) ANum AType RType RNum X Y Z 1 CB GLU 1 8.34725.351 44.432 2 CG GLU 1 8.491 26.847 44.172 3 CD GLU 1 7.393 27.68744.808 4 OE1 GLU 1 6.242 27.209 44.909 5 OE2 GLU 1 7.687 28.837 45.205 6C GLU 1 8.465 24.539 42.087 7 O GLU 1 9.059 24.281 41.031 8 N GLU 110.588 24.923 43.469 9 CA GLU 1 9.160 24.496 43.450 10 N VAL 2 7.17924.881 42.172 11 CA VAL 2 6.233 24.989 41.065 12 CB VAL 2 4.813 24.68841.547 13 CG1 VAL 2 4.629 25.287 42.941 14 CG2 VAL 2 3.785 25.270 40.57615 C VAL 2 6.200 26.366 40.441 16 O VAL 2 5.758 27.343 41.041 17 N THR 36.636 26.426 39.204 18 CA THR 3 6.658 27.675 38.508 19 CB THR 3 8.09528.045 38.222 20 OG1 THR 3 8.949 27.140 38.935 21 CG2 THR 3 8.383 29.46938.663 22 C THR 3 5.895 27.422 37.235 23 O THR 3 6.092 26.400 36.582 24N ILE 4 4.999 28.331 36.895 25 CA ILE 4 4.235 28.161 35.683 26 CB ILE 42.788 27.774 36.016 27 CG2 ILE 4 2.255 28.682 37.113 28 CG1 ILE 4 1.94427.777 34.745 29 CD1 ILE 4 0.536 27.360 34.992 30 C ILE 4 4.303 29.46134.901 31 O ILE 4 3.821 30.498 35.350 32 N GLU 5 4.950 29.403 33.744 33CA GLU 5 5.097 30.575 32.901 34 CB GLU 5 6.589 30.833 32.640 35 CG GLU 57.031 30.993 31.193 36 CD GLU 5 8.540 30.866 31.052 37 OE1 GLU 5 9.19230.421 32.023 38 OE2 GLU 5 9.077 31.209 29.979 39 C GLU 5 4.335 30.28831.626 40 O GLU 5 4.099 29.132 31.295 41 N ALA 6 3.918 31.329 30.924 42CA ALA 6 3.174 31.127 29.692 43 CB ALA 6 1.851 31.847 29.759 44 C ALA 63.965 31.639 28.525 45 O ALA 6 4.288 32.815 28.468 46 N VAL 7 4.30030.761 27.597 47 CA VAL 7 5.030 31.229 26.451 48 CB VAL 7 6.371 30.50426.262 49 CG1 VAL 7 6.414 29.788 24.920 50 CG2 VAL 7 7.491 31.529 26.34051 C VAL 7 4.171 31.098 25.212 52 O VAL 7 3.697 30.015 24.875 53 N PRO 83.941 32.223 24.550 54 CD PRO 8 3.211 32.399 23.274 55 CA PRO 8 4.50033.495 25.032 56 CB PRO 8 4.661 34.304 23.772 57 CG PRO 8 3.500 33.84822.905 58 C PRO 8 3.597 34.213 26.032 59 O PRO 8 2.377 34.204 25.880 60N PRO 9 4.171 34.811 27.091 61 CD PRO 9 5.577 34.914 27.531 62 CA PRO 93.238 35.508 27.985 63 CB PRO 9 4.110 35.967 29.158 64 CG PRO 9 5.52335.886 28.680 65 C PRO 9 2.793 36.657 27.096 66 O PRO 9 3.617 37.17526.354 67 N GLN 10 1.526 37.054 27.133 68 CA GLN 10 1.067 38.125 26.24069 CB GLN 10 2.076 39.271 26.173 70 CG GLN 10 2.047 40.196 27.357 71 CDGLN 10 0.984 41.248 27.217 72 OE1 GLN 10 0.337 41.351 26.182 73 NE2 GLN10 0.793 42.038 28.261 74 C GLN 10 0.947 37.522 24.842 75 O GLN 10 1.84437.670 24.014 76 N VAL 11 −0.167 36.848 24.586 77 CA VAL 11 −0.40436.200 23.303 78 CB VAL 11 −1.173 34.894 23.483 79 CG1 VAL 11 −0.83333.945 22.346 80 CG2 VAL 11 −0.846 34.296 24.836 81 C VAL 11 −1.18237.047 22.318 82 O VAL 11 −1.867 38.000 22.689 83 N ALA 12 −1.095 36.67021.054 84 CA ALA 12 −1.798 37.401 20.023 85 CB ALA 12 −0.834 37.78518.922 86 C ALA 12 −2.949 36.601 19.452 87 O ALA 12 −2.870 35.381 19.32388 N GLU 13 −4.022 37.305 19.120 89 CA GLU 13 −5.192 36.679 18.536 90 CBGLU 13 −6.052 37.740 17.872 91 CG GLU 13 −7.463 37.313 17.606 92 CD GLU13 −8.372 38.499 17.432 93 OE1 GLU 13 −8.551 39.240 18.420 94 OE2 GLU 13−8.897 38.695 16.314 95 C GLU 13 −4.731 35.668 17.492 96 O GLU 13 −3.63535.792 16.949 97 N ASP 14 −5.572 34.676 17.219 98 CA ASP 14 −5.27933.620 16.249 99 CB ASP 14 −5.937 33.983 14.876 100 CG ASP 14 −4.96334.497 13.809 101 OD1 ASP 14 −3.842 34.947 14.127 102 OD2 ASP 14 −5.35334.454 12.616 103 C ASP 14 −3.798 33.197 16.170 104 O ASP 14 −3.23332.969 15.099 105 N ASN 15 −3.201 33.071 17.358 106 CA ASN 15 −1.81032.644 17.551 107 CB ASN 15 −0.900 33.855 17.809 108 CG ASN 15 0.01034.167 16.630 109 OD1 ASN 15 0.013 33.451 15.625 110 ND2 ASN 15 0.78935.240 16.751 111 C ASN 15 −1.814 31.701 18.764 112 O ASN 15 −2.76231.714 19.541 113 N ASN 16 −0.761 30.905 18.938 114 CA ASN 16 −0.70129.934 20.039 115 CB ASN 16 −0.026 28.662 19.543 116 CG ASN 16 −1.01027.649 19.041 117 OD1 ASN 16 −0.823 26.448 19.222 118 ND2 ASN 16 −2.07028.123 18.397 119 C ASN 16 −0.035 30.323 21.361 120 O ASN 16 0.63431.354 21.468 121 N VAL 17 −0.221 29.464 22.366 122 CA VAL 17 0.37229.673 23.689 123 CB VAL 17 −0.469 30.539 24.612 124 CG1 VAL 17 0.44631.468 25.389 125 CG2 VAL 17 −1.529 31.270 23.838 126 C VAL 17 0.56528.405 24.476 127 O VAL 17 −0.238 27.479 24.396 128 N LEU 18 1.61528.394 25.284 129 CA LEU 18 1.907 27.239 26.105 130 CB LEU 18 3.25626.639 25.728 131 CG LEU 18 3.664 25.462 26.615 132 CD1 LEU 18 2.58724.377 26.567 133 CD2 LEU 18 5.004 24.923 26.150 134 C LEU 18 1.92027.605 27.578 135 O LEU 18 2.420 28.667 27.969 136 N LEU 19 1.365 26.70728.384 137 CA LEU 19 1.293 26.885 29.821 138 CB LEU 19 −0.034 26.35630.352 139 CG LEU 19 −1.218 27.289 30.109 140 CD1 LEU 19 −1.038 28.52130.964 141 CD2 LEU 19 −1.310 27.670 28.633 142 C LEU 19 2.430 26.09030.407 143 O LEU 19 2.277 24.913 30.732 144 N LEU 20 3.576 26.743 30.538145 CA LEU 20 4.756 26.092 31.066 146 CB LEU 20 5.994 26.949 30.840 147CG LEU 20 7.285 26.135 30.760 148 CD1 LEU 20 7.046 24.860 29.958 149 CD2LEU 20 8.370 26.972 30.110 150 C LEU 20 4.664 25.741 32.532 151 O LEU 204.201 26.531 33.358 152 N VAL 21 5.143 24.545 32.843 153 CA VAL 21 5.13124.032 34.197 154 CB VAL 21 4.215 22.807 34.262 155 CG1 VAL 21 4.14322.277 35.672 156 CG2 VAL 21 2.837 23.194 33.746 157 C VAL 21 6.55023.652 34.609 158 O VAL 21 7.019 22.563 34.273 159 N HIS 22 7.248 24.54835.315 160 CA HIS 22 8.615 24.246 35.754 161 CB HIS 22 9.429 25.47036.169 162 CG HIS 22 9.337 26.638 35.258 163 CD2 HIS 22 9.297 27.97335.521 164 ND1 HIS 22 9.338 26.530 33.883 165 CE1 HIS 22 9.303 27.74933.343 166 NE2 HIS 22 9.278 28.623 34.332 167 C HIS 22 8.581 23.38936.987 168 O HIS 22 7.645 23.455 37.780 169 N ASN 23 9.663 22.644 37.168170 CA ASN 23 9.832 21.756 38.301 171 CB ASN 23 10.762 22.404 39.323 172CG ASN 23 12.229 22.142 39.004 173 OD1 ASN 23 12.804 22.758 38.102 174ND2 ASN 23 12.837 21.213 39.735 175 C ASN 23 8.501 21.354 38.907 176 OASN 23 8.031 21.908 39.890 177 N LEU 24 7.904 20.381 38.239 178 CA LEU24 6.631 19.790 38.584 179 CB LEU 24 5.977 19.303 37.296 180 CG LEU 244.585 18.694 37.312 181 CD1 LEU 24 4.553 17.596 36.268 182 CD2 LEU 244.245 18.155 38.689 183 C LEU 24 6.988 18.623 39.495 184 O LEU 24 7.36917.553 39.032 185 N PRO 25 6.831 18.803 40.810 186 CD PRO 25 6.30320.027 41.439 187 CA PRO 25 7.161 17.763 41.789 188 CB PRO 25 6.67818.324 43.132 189 CG PRO 25 6.281 19.712 42.899 190 C PRO 25 6.71216.318 41.610 191 O PRO 25 5.702 16.016 40.972 192 N LEU 26 7.527 15.46042.222 193 CA LEU 26 7.415 14.005 42.289 194 CB LEU 26 7.511 13.59343.763 195 CG LEU 26 8.598 14.457 44.418 196 CD1 LEU 26 8.490 14.36945.926 197 CD2 LEU 26 9.975 14.002 43.929 198 C LEU 26 6.196 13.41041.616 199 O LEU 26 5.082 13.900 41.792 200 N ALA 27 6.411 12.327 40.872201 CA ALA 27 5.331 11.732 40.102 202 CB ALA 27 5.877 10.697 39.156 203C ALA 27 4.058 11.234 40.766 204 O ALA 27 3.851 10.052 41.080 205 N LEU28 3.200 12.237 40.878 206 CA LEU 28 1.860 12.234 41.415 207 CB LEU 281.237 13.596 41.128 208 CG LEU 28 1.996 14.804 41.662 209 CD1 LEU 282.580 15.664 40.545 210 CD2 LEU 28 1.021 15.591 42.491 211 C LEU 280.959 11.190 40.812 212 O LEU 28 1.379 10.331 40.046 213 N GLY 29 −0.30811.310 41.177 214 CA GLY 29 −1.317 10.428 40.657 215 C GLY 29 −1.73611.032 39.335 216 O GLY 29 −1.990 10.302 38.391 217 N ALA 30 −1.78712.359 39.251 218 CA ALA 30 −2.187 13.008 38.006 219 CB ALA 30 −3.48512.396 37.505 220 C ALA 30 −2.362 14.513 38.143 221 O ALA 30 −2.42315.041 39.254 222 N PHE 31 −2.440 15.201 37.005 223 CA PHE 31 −2.64916.644 37.015 224 CB PHE 31 −1.470 17.426 36.397 225 CG PHE 31 −0.52616.600 35.553 226 CD1 PHE 31 0.742 16.273 36.031 227 CD2 PHE 31 −0.85916.233 34.254 228 CE1 PHE 31 1.661 15.592 35.227 229 CE2 PHE 31 0.05815.553 33.448 230 CZ PHE 31 1.317 15.236 33.933 231 C PHE 31 −3.93417.038 36.295 232 O PHE 31 −4.458 16.291 35.463 233 N ALA 32 −4.43218.223 36.627 234 CA ALA 32 −5.655 18.742 36.040 235 CB ALA 32 −6.79518.588 37.024 236 C ALA 32 −5.478 20.206 35.675 237 O ALA 32 −4.96220.996 36.475 238 N TRP 33 −5.914 20.565 34.472 239 CA TRP 33 −5.79321.939 33.999 240 CB TRP 33 −5.123 21.975 32.617 241 CG TRP 33 −3.70522.467 32.635 242 CD2 TRP 33 −3.220 23.693 33.188 243 CE2 TRP 33 −1.83823.739 32.974 244 CE3 TRP 33 −3.851 24.749 33.863 245 CD1 TRP 33 −2.60921.840 32.111 246 NE1 TRP 33 −1.481 22.595 32.312 247 CZ2 TRP 33 −1.05224.805 33.396 248 CZ3 TRP 33 −3.069 25.810 34.278 249 CH2 TRP 33 −1.68825.829 34.048 250 C TRP 33 −7.160 22.596 33.916 251 O TRP 33 −7.97622.253 33.062 252 N TYR 34 −7.403 23.544 34.812 253 CA TYR 34 −8.67124.258 34.843 254 CB TYR 34 −9.268 24.213 36.251 255 CG TYR 34 −9.48122.817 36.781 256 CD1 TYR 34 −8.738 22.340 37.856 257 CE1 TYR 34 −8.92621.048 38.351 258 CD2 TYR 34 −10.423 21.969 36.209 259 CE2 TYR 34−10.620 20.678 36.695 260 CZ TYR 34 −9.866 20.224 37.766 261 OH TYR 34−10.041 18.948 38.253 262 C TYR 34 −8.531 25.711 34.401 263 O TYR 34−7.433 26.272 34.359 264 N LYS 35 −9.666 26.313 34.082 265 CA LYS 35−9.714 27.692 33.635 266 CB LYS 35 −10.484 27.750 32.307 267 CG LYS 35−10.801 29.140 31.738 268 CD LYS 35 −11.408 29.009 30.325 269 CE LYS 35−11.841 30.347 29.722 270 NZ LYS 35 −12.528 30.158 28.405 271 C LYS 35−10.412 28.539 34.692 272 O LYS 35 −11.465 28.161 35.194 273 N GLY 36−9.800 29.656 35.067 274 CA GLY 36 −10.439 30.553 36.013 275 C GLY 36−10.360 30.443 37.525 276 O GLY 36 −11.214 31.020 38.198 277 N ASN 37−9.385 29.730 38.082 278 CA ASN 37 −9.277 29.656 39.544 279 CB ASN 37−9.365 31.100 40.114 280 CG ASN 37 −9.477 31.164 41.641 281 OD1 ASN 37−10.210 30.393 42.258 282 ND2 ASN 37 −8.770 32.120 42.251 283 C ASN 37−10.311 28.710 40.190 284 O ASN 37 −10.123 28.267 41.322 285 N THR 38−11.391 28.380 39.484 286 CA THR 38 −12.386 27.470 40.055 287 CB THR 38−13.700 27.427 39.235 288 OG1 THR 38 −13.450 27.862 37.895 289 CG2 THR38 −14.762 28.307 39.873 290 C THR 38 −11.839 26.046 40.086 291 O THR 38−11.673 25.421 39.040 292 N THR 39 −11.557 25.536 41.282 293 CA THR 39−11.052 24.170 41.439 294 CB THR 39 −10.387 23.980 42.832 295 OG1 THR 39−10.417 22.598 43.203 296 CG2 THR 39 −11.115 24.796 43.891 297 C THR 39−12.252 23.233 41.305 298 O THR 39 −12.347 22.204 41.970 299 N ALA 40−13.164 23.603 40.413 300 CA ALA 40 −14.382 22.841 40.199 301 CB ALA 40−15.580 23.771 40.320 302 C ALA 40 −14.476 22.058 38.895 303 O ALA 40−14.212 22.578 37.809 304 N ILE 41 −14.885 20.799 39.027 305 CA ILE 41−15.070 19.895 37.898 306 CB ILE 41 −15.826 18.634 38.337 307 CG2 ILE 41−15.263 17.415 37.631 308 CG1 ILE 41 −15.727 18.477 39.856 309 CD1 ILE41 −17.058 18.210 40.531 310 C ILE 41 −15.897 20.607 36.837 311 O ILE 41−15.950 20.193 35.677 312 N ASP 42 −16.558 21.675 37.268 313 CA ASP 42−17.380 22.496 36.401 314 CB ASP 42 −17.748 23.795 37.127 315 CG ASP 42−18.993 24.455 36.566 316 OD1 ASP 42 −18.907 25.110 35.506 317 OD2 ASP42 −20.064 24.324 37.194 318 C ASP 42 −16.540 22.825 35.182 319 O ASP 42−17.032 22.831 34.053 320 N LYS 43 −15.257 23.071 35.430 321 CA LYS 43−14.335 23.446 34.372 322 CB LYS 43 −13.943 24.914 34.554 323 CG LYS 43−15.024 25.780 35.195 324 CD LYS 43 −15.987 26.329 34.143 325 CE LYS 43−16.654 27.625 34.597 326 NZ LYS 43 −17.005 28.511 33.447 327 C LYS 43−13.066 22.607 34.257 328 O LYS 43 −11.965 23.130 34.423 329 N GLU 44−13.205 21.319 33.959 330 CA GLU 44 −12.030 20.466 33.812 331 CB GLU 44−12.250 19.092 34.441 332 CG GLU 44 −11.089 18.143 34.173 333 CD GLU 44−11.047 16.967 35.126 334 OE1 GLU 44 −10.883 17.186 36.346 335 OE2 GLU44 −11.174 15.819 34.648 336 C GLU 44 −11.701 20.275 32.347 337 O GLU 44−12.521 19.755 31.591 338 N ILE 45 −10.501 20.688 31.949 339 CA ILE 45−10.088 20.545 30.562 340 CB ILE 45 −9.347 21.766 30.035 341 CG2 ILE 45−9.435 21.761 28.517 342 CG1 ILE 45 −9.902 23.040 30.678 343 CD1 ILE 45−9.672 24.296 29.865 344 C ILE 45 −9.194 19.372 30.284 345 O ILE 45−9.182 18.856 29.167 346 N ALA 46 −8.428 18.959 31.284 347 CA ALA 46−7.530 17.841 31.084 348 CB ALA 46 −6.381 18.267 30.189 349 C ALA 46−6.987 17.248 32.368 350 O ALA 46 −6.720 17.959 33.343 351 N ARG 47−6.822 15.928 32.342 352 CA ARG 47 −6.298 15.178 33.470 353 CB ARG 47−7.441 14.575 34.280 354 CG ARG 47 −7.015 13.641 35.408 355 CD ARG 47−8.247 13.002 36.050 356 NE ARG 47 −9.462 13.361 35.316 357 CZ ARG 47−10.486 12.542 35.095 358 NH1 ARG 47 −10.455 11.297 35.554 359 NH2 ARG47 −11.537 12.966 34.401 360 C ARG 47 −5.416 14.070 32.927 361 O ARG 47−5.896 13.124 32.308 362 N PHE 48 −4.115 14.206 33.135 363 CA PHE 48−3.178 13.199 32.672 364 CB PHE 48 −1.966 13.856 32.018 365 CG PHE 48−0.848 12.904 31.696 366 CD1 PHE 48 −0.055 12.372 32.705 367 CD2 PHE 48−0.573 12.561 30.376 368 CE1 PHE 48 1.001 11.520 32.404 369 CE2 PHE 480.483 11.709 30.063 370 CZ PHE 48 1.270 11.186 31.079 371 C PHE 48−2.774 12.448 33.917 372 O PHE 48 −2.696 13.029 34.993 373 N VAL 49−2.508 11.160 33.764 374 CA VAL 49 −2.160 10.329 34.900 375 CB VAL 49−3.265 9.311 35.153 376 CG1 VAL 49 −3.390 9.011 36.624 377 CG2 VAL 49−4.551 9.854 34.625 378 C VAL 49 −0.856 9.574 34.750 379 O VAL 49 −0.7048.745 33.855 380 N PRO 50 0.111 9.865 35.630 381 CD PRO 50 0.015 10.90036.670 382 CA PRO 50 1.419 9.203 35.602 383 CB PRO 50 2.161 9.771 36.819384 CG PRO 50 1.248 10.723 37.473 385 C PRO 50 1.315 7.685 35.687 386 OPRO 50 1.290 6.986 34.674 387 N ASN 51 1.251 7.201 36.920 388 CA ASN 511.177 5.784 37.218 389 CB ASN 51 0.438 5.604 38.552 390 CG ASN 51 1.2666.105 39.734 391 OD1 ASN 51 1.184 5.572 40.838 392 ND2 ASN 51 2.0767.130 39.494 393 C ASN 51 0.616 4.887 36.104 394 O ASN 51 0.984 3.72136.014 395 N SER 52 −0.246 5.423 35.246 396 CA SER 52 −0.778 4.64234.135 397 CB SER 52 −2.043 3.901 34.562 398 OG SER 52 −1.712 2.72835.285 399 C SER 52 −1.073 5.519 32.922 400 O SER 52 −2.207 5.576 32.451401 N ASN 53 −0.036 6.186 32.422 402 CA ASN 53 −0.128 7.086 31.269 403CB ASN 53 1.077 6.875 30.345 404 CG ASN 53 2.395 7.181 31.022 405 OD1ASN 53 2.483 7.205 32.250 406 ND2 ASN 53 3.431 7.415 30.222 407 C ASN 53−1.406 7.005 30.438 408 O ASN 53 −1.634 6.019 29.740 409 N MET 54 −2.2318.050 30.517 410 CA MET 54 −3.478 8.111 29.758 411 CB MET 54 −4.4677.044 30.230 412 CG MET 54 −5.813 7.131 29.521 413 SD MET 54 −6.2205.675 28.533 414 CE MET 54 −5.644 6.180 26.893 415 C MET 54 −4.150 9.47729.811 416 O MET 54 −4.214 10.128 30.849 417 N ASN 55 −4.693 9.86728.670 418 CA ASN 55 −5.333 11.153 28.482 419 CB ASN 55 −5.062 11.62427.084 420 CG ASN 55 −3.754 12.281 26.945 421 OD1 ASN 55 −2.716 11.75027.330 422 ND2 ASN 55 −3.811 13.449 26.331 423 C ASN 55 −6.827 11.27128.638 424 O ASN 55 −7.544 11.059 27.660 425 N PHE 56 −7.333 11.60929.814 426 CA PHE 56 −8.772 11.808 29.866 427 CB PHE 56 −9.470 11.05631.007 428 CG PHE 56 −8.568 10.201 31.837 429 CD1 PHE 56 −8.232 10.60833.119 430 CD2 PHE 56 −8.191 8.930 31.413 431 CE1 PHE 56 −7.514 9.78233.962 432 CE2 PHE 56 −7.467 8.090 32.254 433 CZ PHE 56 −7.145 8.51133.537 434 C PHE 56 −9.048 13.307 29.994 435 O PHE 56 −8.365 14.01930.734 436 N THR 57 −10.044 13.779 29.255 437 CA THR 57 −10.412 15.19029.262 438 CB THR 57 −10.724 15.685 27.827 439 OG1 THR 57 −11.685 16.74527.881 440 CG2 THR 57 −11.284 14.551 26.976 441 C THR 57 −11.628 15.45130.145 442 O THR 57 −12.355 14.528 30.505 443 N GLY 58 −11.837 16.71630.498 444 CA GLY 58 −12.979 17.076 31.318 445 C GLY 58 −14.024 17.76830.464 446 O GLY 58 −13.890 17.812 29.241 447 N GLN 59 −15.063 18.30631.095 448 CA GLN 59 −16.126 19.003 30.367 449 CB GLN 59 −17.274 19.34631.321 450 CG GLN 59 −18.574 19.794 30.654 451 CD GLN 59 −19.669 20.10131.668 452 OE1 GLN 59 −20.534 20.949 31.435 453 NE2 GLN 59 −19.63519.410 32.802 454 C GLN 59 −15.540 20.283 29.787 455 O GLN 59 −16.15621.347 29.840 456 N ALA 60 −14.346 20.175 29.220 457 CA ALA 60 −13.69021.341 28.672 458 CB ALA 60 −12.475 21.627 29.453 459 C ALA 60 −13.34821.342 27.200 460 O ALA 60 −12.564 20.527 26.710 461 N TYR 61 −13.96822.301 26.526 462 CA TYR 61 −13.803 22.587 25.112 463 CB TYR 61 −13.24623.997 24.990 464 CG TYR 61 −14.189 25.004 24.392 465 CD1 TYR 61 −15.56024.760 24.312 466 CE1 TYR 61 −16.411 25.672 23.693 467 CD2 TYR 61−13.697 26.190 23.853 468 CE2 TYR 61 −14.534 27.102 23.236 469 CZ TYR 61−15.887 26.841 23.156 470 OH TYR 61 −16.702 27.733 22.501 471 C TYR 61−12.929 21.638 24.298 472 O TYR 61 −13.379 21.077 23.298 473 N SER 62−11.676 21.494 24.724 474 CA SER 62 −10.689 20.641 24.059 475 CB SER 62−10.853 19.176 24.482 476 OG SER 62 −9.943 18.348 23.777 477 C SER 62−10.753 20.739 22.543 478 O SER 62 −10.514 19.758 21.833 479 N GLY 63−11.090 21.925 22.047 480 CA GLY 63 −11.150 22.108 20.613 481 C GLY 63−9.750 22.428 20.129 482 O GLY 63 −9.412 22.215 18.961 483 N ARG 64−8.930 22.934 21.049 484 CA ARG 64 −7.557 23.312 20.739 485 CB ARG 64−7.547 24.615 19.928 486 CG ARG 64 −8.931 25.215 19.668 487 CD ARG 64−9.043 26.645 20.154 488 NE ARG 64 −10.064 26.812 21.187 489 CZ ARG 64−9.907 27.584 22.252 490 NH1 ARG 64 −8.777 28.244 22.406 491 NH2 ARG 64−10.870 27.697 23.151 492 C ARG 64 −6.714 23.494 22.002 493 O ARG 64−6.246 24.596 22.294 494 N GLU 65 −6.513 22.414 22.747 495 CA GLU 65−5.725 22.480 23.967 496 CB GLU 65 −6.643 22.759 25.148 497 CG GLU 65−7.522 23.967 24.930 498 CD GLU 65 −8.697 24.018 25.868 499 OE1 GLU 65−8.509 23.683 27.052 500 OE2 GLU 65 −9.803 24.396 25.419 501 C GLU 65−5.013 21.164 24.179 502 O GLU 65 −5.523 20.124 23.780 503 N ILE 66−3.834 21.193 24.793 504 CA ILE 66 −3.115 19.951 25.041 505 CB ILE 66−2.154 19.590 23.888 506 CG2 ILE 66 −1.256 18.436 24.301 507 CG1 ILE 66−2.950 19.134 22.669 508 CD1 ILE 66 −2.694 19.958 21.438 509 C ILE 66−2.319 19.934 26.326 510 O ILE 66 −1.628 20.893 26.661 511 N ILE 67−2.425 18.814 27.032 512 CA ILE 67 −1.716 18.602 28.290 513 CB ILE 67−2.591 17.830 29.294 514 CG2 ILE 67 −3.229 16.634 28.601 515 CG1 ILE 67−1.741 17.351 30.474 516 CD1 ILE 67 −2.005 18.096 31.756 517 C ILE 67−0.493 17.754 27.970 518 O ILE 67 −0.505 17.009 26.995 519 N TYR 680.555 17.853 28.783 520 CA TYR 68 1.769 17.078 28.539 521 CB TYR 682.909 18.004 28.107 522 CG TYR 68 2.798 18.568 26.705 523 CD1 TYR 683.893 18.553 25.849 524 CE1 TYR 68 3.815 19.086 24.564 525 CD2 TYR 681.611 19.136 26.240 526 CE2 TYR 68 1.526 19.672 24.952 527 CZ TYR 682.635 19.642 24.119 528 OH TYR 68 2.568 20.147 22.837 529 C TYR 68 2.21516.287 29.766 530 O TYR 68 1.713 16.488 30.873 531 N SER 69 3.172 15.38929.560 532 CA SER 69 3.699 14.562 30.639 533 CB SER 69 4.622 13.48030.074 534 OG SER 69 4.604 13.482 28.651 535 C SER 69 4.463 15.42331.636 536 O SER 69 4.517 15.103 32.819 537 N ASN 70 5.074 16.504 31.159538 CA ASN 70 5.790 17.389 32.066 539 CB ASN 70 6.799 18.303 31.328 540CG ASN 70 6.299 18.812 29.968 541 OD1 ASN 70 5.725 18.070 29.168 542 ND2ASN 70 6.533 20.106 29.746 543 C ASN 70 4.693 18.193 32.730 544 O ASN 704.946 19.064 33.557 545 N GLY 71 3.462 17.850 32.355 546 CA GLY 71 2.27818.489 32.893 547 C GLY 71 2.073 19.899 32.395 548 O GLY 71 1.924 20.81533.185 549 N SER 72 2.047 20.089 31.085 550 CA SER 72 1.866 21.43530.561 551 CB SER 72 3.192 21.960 30.016 552 OG SER 72 4.205 21.84631.006 553 C SER 72 0.780 21.521 29.505 554 O SER 72 0.353 20.506 28.943555 N LEU 73 0.343 22.743 29.228 556 CA LEU 73 −0.734 22.932 28.280 557CB LEU 73 −1.995 23.325 29.034 558 CG LEU 73 −3.271 23.043 28.264 559CD1 LEU 73 −3.946 21.849 28.889 560 CD2 LEU 73 −4.180 24.258 28.297 561C LEU 73 −0.511 23.933 27.170 562 O LEU 73 −0.264 25.111 27.416 563 NLEU 74 −0.591 23.461 25.936 564 CA LEU 74 −0.451 24.373 24.825 565 CBLEU 74 0.073 23.688 23.567 566 CG LEU 74 −0.431 24.436 22.322 567 CD1LEU 74 0.567 25.518 21.915 568 CD2 LEU 74 −0.676 23.460 21.200 569 C LEU74 −1.873 24.799 24.577 570 O LEU 74 −2.809 24.071 24.889 571 N PHE 75−2.032 25.977 24.010 572 CA PHE 75 −3.342 26.483 23.715 573 CB PHE 75−3.705 27.583 24.691 574 CG PHE 75 −5.127 27.546 25.125 575 CD1 PHE 75−5.468 27.075 26.388 576 CD2 PHE 75 −6.130 27.997 24.282 577 CE1 PHE 75−6.797 27.054 26.806 578 CE2 PHE 75 −7.457 27.981 24.692 579 CZ PHE 75−7.794 27.511 25.953 580 C PHE 75 −3.268 27.039 22.326 581 O PHE 75−2.542 28.002 22.067 582 N GLN 76 −3.994 26.408 21.420 583 CA GLN 76−4.009 26.870 20.051 584 CB GLN 76 −4.394 25.732 19.113 585 CG GLN 76−3.531 24.494 19.293 586 CD GLN 76 −3.334 23.718 18.003 587 OE1 GLN 76−4.292 23.205 17.423 588 NE2 GLN 76 −2.087 23.626 17.548 589 C GLN 76−5.034 27.976 19.992 590 O GLN 76 −5.705 28.245 20.986 591 N MET 77−5.140 28.613 18.832 592 CA MET 77 −6.080 29.707 18.608 593 CB MET 77−7.145 29.286 17.595 594 CG MET 77 −6.633 28.383 16.482 595 SD MET 77−6.639 29.130 14.817 596 CE MET 77 −7.657 30.610 15.055 597 C MET 77−6.773 30.221 19.863 598 O MET 77 −7.887 29.802 20.178 599 N ILE 78−6.111 31.124 20.576 600 CA ILE 78 −6.680 31.708 21.783 601 CB ILE 78−5.582 32.205 22.733 602 CG2 ILE 78 −6.197 32.999 23.862 603 CG1 ILE 78−4.806 31.018 23.299 604 CD1 ILE 78 −4.040 30.244 22.264 605 C ILE 78−7.512 32.890 21.319 606 O ILE 78 −7.301 33.407 20.221 607 N THR 79−8.461 33.320 22.136 608 CA THR 79 −9.294 34.446 21.751 609 CB THR 79−10.574 33.963 21.053 610 OG1 THR 79 −10.232 32.985 20.063 611 CG2 THR79 −11.281 35.125 20.377 612 C THR 79 −9.659 35.251 22.976 613 O THR 79−9.661 34.722 24.078 614 N MET 80 −9.952 36.533 22.783 615 CA MET 80−10.316 37.406 23.894 616 CB MET 80 −11.196 38.560 23.388 617 CG MET 80−12.687 38.424 23.712 618 SD MET 80 −13.329 39.702 24.832 619 CE MET 80−15.010 39.079 25.146 620 C MET 80 −11.053 36.621 24.981 621 O MET 80−10.823 36.814 26.176 622 N LYS 81 −11.925 35.722 24.544 623 CA LYS 81−12.720 34.894 25.438 624 CB LYS 81 −13.783 34.160 24.615 625 CG LYS 81−13.960 34.719 23.198 626 CD LYS 81 −15.418 35.052 22.893 627 CE LYS 81−15.582 36.480 22.381 628 NZ LYS 81 −15.515 36.570 20.894 629 C LYS 81−11.865 33.896 26.226 630 O LYS 81 −12.236 33.467 27.322 631 N ASP 82−10.718 33.537 25.657 632 CA ASP 82 −9.780 32.596 26.266 633 CB ASP 82−8.926 31.940 25.179 634 CG ASP 82 −9.392 30.545 24.823 635 OD1 ASP 82−9.979 29.857 25.689 636 OD2 ASP 82 −9.163 30.138 23.669 637 C ASP 82−8.860 33.323 27.241 638 O ASP 82 −8.117 32.700 27.997 639 N MET 83−8.905 34.648 27.204 640 CA MET 83 −8.069 35.466 28.069 641 CB MET 83−8.285 36.942 27.751 642 CG MET 83 −7.197 37.860 28.276 643 SD MET 83−7.281 39.481 27.485 644 CE MET 83 −5.863 40.299 28.215 645 C MET 83−8.365 35.222 29.536 646 O MET 83 −9.458 34.785 29.894 647 N GLY 84−7.390 35.518 30.387 648 CA GLY 84 −7.587 35.323 31.809 649 C GLY 84−6.655 34.328 32.474 650 O GLY 84 −5.683 33.862 31.883 651 N VAL 85−6.968 33.995 33.722 652 CA VAL 85 −6.159 33.070 34.507 653 CB VAL 85−6.239 33.402 36.001 654 CG1 VAL 85 −7.606 33.982 36.314 655 CG2 VAL 85−5.987 32.148 36.834 656 C VAL 85 −6.575 31.622 34.346 657 O VAL 85−7.743 31.312 34.139 658 N TYR 86 −5.598 30.737 34.463 659 CA TYR 86−5.851 29.322 34.355 660 CB TYR 86 −5.271 28.794 33.049 661 CG TYR 86−6.112 29.205 31.868 662 CD1 TYR 86 −6.041 30.502 31.350 663 CE1 TYR 86−6.862 30.904 30.286 664 CD2 TYR 86 −7.018 28.316 31.297 665 CE2 TYR 86−7.840 28.704 30.236 666 CZ TYR 86 −7.760 29.999 29.735 667 OH TYR 86−8.581 30.378 28.693 668 C TYR 86 −5.200 28.666 35.553 669 O TYR 86−4.266 29.218 36.147 670 N THR 87 −5.714 27.500 35.926 671 CA THR 87−5.170 26.789 37.069 672 CB THR 87 −6.009 27.039 38.331 673 OG1 THR 87−5.844 28.399 38.751 674 CG2 THR 87 −5.554 26.118 39.460 675 C THR 87−5.013 25.300 36.881 676 O THR 87 −5.866 24.616 36.298 677 N LEU 88−3.903 24.803 37.394 678 CA LEU 88 −3.598 23.407 37.298 679 CB LEU 88−2.232 23.230 36.657 680 CG LEU 88 −1.572 21.890 36.945 681 CD1 LEU 88−1.341 21.179 35.628 682 CD2 LEU 88 −0.277 22.094 37.694 683 C LEU 88−3.580 22.837 38.708 684 O LEU 88 −3.158 23.497 39.656 685 N ASP 89−4.062 21.614 38.844 686 CA ASP 89 −4.060 20.980 40.135 687 CB ASP 89−5.466 20.835 40.688 688 CG ASP 89 −5.466 20.533 42.165 689 OD1 ASP 89−4.427 20.041 42.660 690 OD2 ASP 89 −6.488 20.789 42.834 691 C ASP 89−3.453 19.632 39.935 692 O ASP 89 −3.650 18.992 38.911 693 N MET 90−2.702 19.207 40.927 694 CA MET 90 −2.048 17.931 40.860 695 CB MET 90−0.553 18.149 40.672 696 CG MET 90 −0.253 19.287 39.713 697 SD MET 900.923 20.491 40.358 698 CE MET 90 0.184 20.923 41.913 699 C MET 90−2.336 17.175 42.139 700 O MET 90 −2.652 17.772 43.173 701 N THR 91−2.233 15.855 42.068 702 CA THR 91 −2.503 15.044 43.233 703 CB THR 91−4.001 14.788 43.385 704 OG1 THR 91 −4.720 16.011 43.182 705 CG2 THR 91−4.299 14.236 44.763 706 C THR 91 −1.812 13.703 43.203 707 O THR 91−1.657 13.083 42.153 708 N ASP 92 −1.403 13.281 44.388 709 CA ASP 92−0.748 12.007 44.630 710 CB ASP 92 0.771 12.185 44.762 711 CG ASP 921.160 13.487 45.458 712 OD1 ASP 92 0.492 14.516 45.230 713 OD2 ASP 922.145 13.484 46.231 714 C ASP 92 −1.362 11.729 45.983 715 O ASP 92−1.165 12.519 46.904 716 N GLU 93 −2.117 10.648 46.138 717 CA GLU 93−2.715 10.477 47.445 718 CB GLU 93 −3.787 9.392 47.470 719 CG GLU 93−5.063 9.947 48.095 720 CD GLU 93 −5.284 11.409 47.734 721 OE1 GLU 93−5.873 11.649 46.660 722 OE2 GLU 93 −4.869 12.308 48.506 723 C GLU 93−1.739 10.328 48.587 724 O GLU 93 −1.086 9.308 48.813 725 N ASN 94−1.679 11.448 49.279 726 CA ASN 94 −0.867 11.736 50.428 727 CB ASN 940.596 11.367 50.190 728 CG ASN 94 1.175 10.538 51.323 729 OD1 ASN 941.955 9.614 51.099 730 ND2 ASN 94 0.787 10.865 52.552 731 C ASN 94−1.088 13.240 50.351 732 O ASN 94 −1.137 13.922 51.369 733 N TYR 95−1.254 13.735 49.117 734 CA TYR 95 −1.535 15.149 48.875 735 CB TYR 95−0.432 16.035 49.444 736 CG TYR 95 −1.058 17.151 50.234 737 CD1 TYR 95−1.341 16.986 51.589 738 CE1 TYR 95 −2.060 17.944 52.301 739 CD2 TYR 95−1.500 18.317 49.606 740 CE2 TYR 95 −2.222 19.285 50.309 741 CZ TYR 95−2.501 19.088 51.657 742 OH TYR 95 −3.241 20.012 52.365 743 C TYR 95−1.869 15.658 47.471 744 O TYR 95 −1.303 15.222 46.469 745 N ARG 96−2.805 16.608 47.437 746 CA ARG 96 −3.268 17.267 46.215 747 CB ARG 96−4.786 17.055 46.035 748 CG ARG 96 −5.568 18.250 45.450 749 CD ARG 96−7.080 17.966 45.305 750 NE ARG 96 −7.913 19.110 45.708 751 CZ ARG 96−9.219 19.244 45.454 752 NH1 ARG 96 −9.879 18.308 44.789 753 NH2 ARG 96−9.872 20.323 45.871 754 C ARG 96 −2.971 18.763 46.373 755 O ARG 96−3.512 19.414 47.271 756 N ARG 97 −2.106 19.307 45.520 757 CA ARG 97−1.767 20.725 45.593 758 CB ARG 97 −0.250 20.898 45.679 759 CG ARG 970.379 20.138 46.842 760 CD ARG 97 1.906 20.212 46.837 761 NE ARG 972.509 19.298 47.813 762 CZ ARG 97 3.820 19.154 48.011 763 NH1 ARG 974.691 19.866 47.304 764 NH2 ARG 97 4.268 18.293 48.919 765 C ARG 97−2.312 21.434 44.363 766 O ARG 97 −2.285 20.883 43.267 767 N THR 98−2.812 22.651 44.546 768 CA THR 98 −3.380 23.427 43.447 769 CB THR 98−4.580 24.260 43.926 770 OG1 THR 98 −4.894 23.912 45.281 771 CG2 THR 98−5.788 24.008 43.047 772 C THR 98 −2.367 24.385 42.842 773 O THR 98−1.990 24.260 41.678 774 N GLN 99 −1.958 25.353 43.657 775 CA GLN 99−0.981 26.385 43.307 776 CB GLN 99 0.299 26.147 44.098 777 CG GLN 990.738 27.327 44.937 778 CD GLN 99 1.912 26.989 45.826 779 OE1 GLN 991.737 26.564 46.969 780 NE2 GLN 99 3.123 27.174 45.307 781 C GLN 99−0.621 26.568 41.823 782 O GLN 99 0.538 26.459 41.440 783 N ALA 100−1.613 26.873 40.999 784 CA ALA 100 −1.371 27.063 39.579 785 CB ALA 100−2.021 25.951 38.804 786 C ALA 100 −1.848 28.418 39.064 787 O ALA 100−2.544 28.510 38.053 788 N THR 101 −1.474 29.476 39.767 789 CA THR 101−1.841 30.809 39.329 790 CB THR 101 −1.397 31.885 40.343 791 OG1 THR 101−1.676 31.437 41.676 792 CG2 THR 101 −2.117 33.206 40.073 793 C THR 101−1.091 31.053 38.023 794 O THR 101 0.124 30.872 37.960 795 N VAL 102−1.812 31.433 36.977 796 CA VAL 102 −1.175 31.722 35.703 797 CB VAL 102−0.558 30.461 35.071 798 CG1 VAL 102 −0.975 30.300 33.624 799 CG2 VAL102 0.929 30.588 35.126 800 C VAL 102 −2.132 32.395 34.745 801 O VAL 102−3.043 31.785 34.183 802 N ARG 103 −1.909 33.688 34.588 803 CA ARG 103−2.728 34.516 33.732 804 CB ARG 103 −3.262 35.699 34.540 805 CG ARG 103−4.510 36.351 33.987 806 CD ARG 103 −4.706 37.744 34.579 807 NE ARG 103−4.847 37.722 36.034 808 CZ ARG 103 −3.836 37.858 36.889 809 NH1 ARG 103−2.599 38.027 36.440 810 NH2 ARG 103 −4.061 37.829 38.198 811 C ARG 103−1.860 35.025 32.605 812 O ARG 103 −0.659 35.210 32.771 813 N PHE 104−2.468 35.237 31.451 814 CA PHE 104 −1.741 35.761 30.313 815 CB PHE 104−1.299 34.631 29.377 816 CG PHE 104 −2.419 33.754 28.903 817 CD1 PHE 104−2.868 32.694 29.679 818 CD2 PHE 104 −3.009 33.973 27.661 819 CE1 PHE104 −3.897 31.866 29.227 820 CE2 PHE 104 −4.039 33.152 27.200 821 CZ PHE104 −4.483 32.095 27.982 822 C PHE 104 −2.690 36.721 29.615 823 O PHE104 −3.855 36.831 30.012 824 N HIS 105 −2.207 37.422 28.592 825 CA HIS105 −3.054 38.380 27.886 826 CB HIS 105 −2.582 39.800 28.195 827 CG HIS105 −2.648 40.141 29.652 828 CD2 HIS 105 −1.687 40.228 30.594 829 ND1HIS 105 −3.846 40.374 30.301 830 CE1 HIS 105 −3.608 40.587 31.584 831NE2 HIS 105 −2.308 40.504 31.790 832 C HIS 105 −3.137 38.168 26.383 833O HIS 105 −2.169 37.781 25.745 834 N VAL 106 −4.315 38.415 25.828 835 CAVAL 106 −4.535 38.259 24.403 836 CB VAL 106 −5.904 37.613 24.108 837 CG1VAL 106 −6.899 38.676 23.601 838 CG2 VAL 106 −5.742 36.513 23.081 839 CVAL 106 −4.525 39.639 23.795 840 O VAL 106 −4.763 40.628 24.491 841 NHIS 107 −4.277 39.714 22.495 842 CA HIS 107 −4.258 41.010 21.861 843 CBHIS 107 −2.872 41.615 21.992 844 CG HIS 107 −2.593 42.128 23.369 845 CD2HIS 107 −1.745 41.685 24.324 846 ND1 HIS 107 −3.259 43.201 23.909 847CE1 HIS 107 −2.835 43.408 25.141 848 NE2 HIS 107 −1.910 42.498 25.420849 C HIS 107 −4.728 41.083 20.430 850 O HIS 107 −4.486 40.196 19.610851 N GLN 108 −5.431 42.168 20.160 852 CA GLN 108 −5.955 42.437 18.847853 CB GLN 108 −7.164 43.360 18.963 854 CG GLN 108 −8.474 42.627 19.142855 CD GLN 108 −8.962 42.030 17.843 856 OE1 GLN 108 −8.387 42.272 16.782857 NE2 GLN 108 −10.029 41.247 17.916 858 C GLN 108 −4.831 43.139 18.101859 O GLN 108 −4.343 44.185 18.535 860 N PRO 109 −4.386 42.560 16.978861 CD PRO 109 −4.875 41.320 16.360 862 CA PRO 109 −3.306 43.178 16.199863 CB PRO 109 −3.215 42.308 14.943 864 CG PRO 109 −4.490 41.503 14.924865 C PRO 109 −3.713 44.608 15.878 866 O PRO 109 −4.867 44.857 15.541867 N VAL 110 −2.780 45.548 15.984 868 CA VAL 110 −3.114 46.943 15.722869 CB VAL 110 −2.045 47.897 16.247 870 CG1 VAL 110 −2.639 49.286 16.358871 CG2 VAL 110 −1.540 47.428 17.594 872 C VAL 110 −3.338 47.294 14.267873 O VAL 110 −2.988 46.535 13.361 874 N THR 111 −3.931 48.461 14.059875 CA THR 111 −4.199 48.960 12.725 876 CB THR 111 −5.689 49.231 12.527877 OG1 THR 111 −6.093 50.311 13.380 878 CG2 THR 111 −6.500 47.99112.861 879 C THR 111 −3.445 50.267 12.591 880 O THR 111 −3.029 50.85113.588 881 N GLN 112 −3.273 50.730 11.362 882 CA GLN 112 −2.559 51.97511.125 883 CB GLN 112 −2.098 52.039 9.669 884 CG GLN 112 −1.694 53.4239.200 885 CD GLN 112 −0.199 53.553 8.982 886 OE1 GLN 112 0.531 52.5608.973 887 NE2 GLN 112 0.267 54.785 8.806 888 C GLN 112 −3.445 53.17311.442 889 O GLN 112 −4.640 53.165 11.148 890 N PRO 113 −2.867 54.22112.058 891 CD PRO 113 −1.455 54.321 12.473 892 CA PRO 113 −3.610 55.43212.413 893 CB PRO 113 −2.844 55.967 13.611 894 CG PRO 113 −1.417 55.59913.302 895 C PRO 113 −3.607 56.427 11.257 896 O PRO 113 −3.727 56.04310.094 897 N PHE 114 −3.457 57.703 11.590 898 CA PHE 114 −3.423 58.75710.592 899 CB PHE 114 −4.466 58.466 9.497 900 CG PHE 114 −5.324 59.6389.115 901 CD1 PHE 114 −4.851 60.614 8.243 902 CD2 PHE 114 −6.628 59.7379.588 903 CE1 PHE 114 −5.670 61.671 7.841 904 CE2 PHE 114 −7.453 60.7879.192 905 CZ PHE 114 −6.972 61.756 8.318 906 C PHE 114 −3.651 60.10911.256 907 O PHE 114 −4.723 60.389 11.800 908 N LEU 115 −2.606 60.93111.232 909 CA LEU 115 −2.666 62.260 11.814 910 CB LEU 115 −1.281 62.90211.877 911 CG LEU 115 −0.231 62.475 12.896 912 CD1 LEU 115 0.631 61.39012.301 913 CD2 LEU 115 0.627 63.669 13.265 914 C LEU 115 −3.543 63.15210.971 915 O LEU 115 −3.850 62.861 9.819 916 N GLN 116 −3.931 64.25811.571 917 CA GLN 116 −4.739 65.259 10.919 918 CB GLN 116 −6.222 65.08011.256 919 CG GLN 116 −7.053 64.427 10.158 920 CD GLN 116 −8.557 64.57310.380 921 OE1 GLN 116 −9.003 65.410 11.167 922 NE2 GLN 116 −9.34263.756 9.683 923 C GLN 116 −4.205 66.491 11.609 924 O GLN 116 −4.12366.537 12.835 925 N VAL 117 −3.771 67.465 10.836 926 CA VAL 117 −3.27668.682 11.434 927 CB VAL 117 −1.747 68.800 11.382 928 CG1 VAL 117 −1.31269.991 12.219 929 CG2 VAL 117 −1.108 67.525 11.895 930 C VAL 117 −3.87669.762 10.587 931 O VAL 117 −4.031 69.605 9.374 932 N THR 118 −4.23270.862 11.221 933 CA THR 118 −4.812 71.941 10.474 934 CB THR 118 −6.13472.390 11.121 935 OG1 THR 118 −7.222 71.789 10.401 936 CG2 THR 118−6.280 73.897 11.088 937 C THR 118 −3.795 73.058 10.384 938 O THR 118−3.464 73.706 11.376 939 N ASN 119 −3.279 73.227 9.170 940 CA ASN 119−2.294 74.241 8.841 941 CB ASN 119 −2.647 75.564 9.526 942 CG ASN 119−2.671 76.723 8.555 943 OD1 ASN 119 −1.677 76.979 7.879 944 ND2 ASN 119−3.793 77.430 8.469 945 C ASN 119 −0.852 73.852 9.151 946 O ASN 119−0.349 74.083 10.245 947 N THR 120 −0.196 73.248 8.169 948 CA THR 1201.194 72.853 8.299 949 CB THR 120 1.691 72.163 7.005 950 OG1 THR 1201.575 70.745 7.153 951 CG2 THR 120 3.149 72.523 6.702 952 C THR 1201.963 74.149 8.509 953 O THR 120 3.063 74.156 9.058 954 N THR 121 1.35675.244 8.065 955 CA THR 121 1.950 76.571 8.168 956 CB THR 121 1.52877.456 6.977 957 OG1 THR 121 2.182 77.002 5.786 958 CG2 THR 121 1.89178.913 7.238 959 C THR 121 1.524 77.271 9.448 960 O THR 121 0.351 77.6119.612 961 N VAL 122 2.468 77.488 10.358 962 CA VAL 122 2.134 78.17311.597 963 CB VAL 122 1.882 77.209 12.763 964 CG1 VAL 122 1.059 77.92513.808 965 CG2 VAL 122 1.130 75.983 12.284 966 C VAL 122 3.140 79.21112.061 967 O VAL 122 4.320 79.173 11.720 968 N LYS 123 2.620 80.13212.865 969 CA LYS 123 3.353 81.255 13.431 970 CB LYS 123 2.402 82.43713.595 971 CG LYS 123 2.306 83.368 12.408 972 CD LYS 123 1.550 84.63312.797 973 CE LYS 123 1.006 85.355 11.576 974 NZ LYS 123 0.424 86.67911.933 975 C LYS 123 3.988 80.974 14.785 976 O LYS 123 3.411 80.28715.627 977 N GLU 124 5.173 81.538 14.992 978 CA GLU 124 5.875 81.37816.256 979 CB GLU 124 7.205 82.134 16.222 980 CG GLU 124 8.357 81.39916.889 981 CD GLU 124 9.689 82.114 16.720 982 OE1 GLU 124 9.768 83.31617.053 983 OE2 GLU 124 10.657 81.472 16.258 984 C GLU 124 4.981 81.95617.342 985 O GLU 124 4.536 83.098 17.237 986 N LEU 125 4.708 81.15718.369 987 CA LEU 125 3.867 81.578 19.484 988 CB LEU 125 4.249 82.99719.931 989 CG LEU 125 5.726 83.142 20.327 990 CDI LEU 125 6.027 84.58120.704 991 CD2 LEU 125 6.034 82.212 21.492 992 C LEU 125 2.376 81.48619.167 993 O LEU 125 1.563 82.237 19.705 994 N ASP 126 2.036 80.55318.284 995 CA ASP 126 0.651 80.312 17.897 996 CB ASP 126 0.483 80.48116.382 997 CG ASP 126 0.073 81.893 15.990 998 CD1 ASP 126 0.000 82.76716.880 999 CD2 ASP 126 −0.179 82.127 14.788 1000 C ASP 126 0.316 78.88018.321 1001 O ASP 126 0.966 78.339 19.210 1002 N SER 127 −0.665 78.25217.686 1003 CA SER 127 −1.024 76.895 18.075 1004 CB SER 127 −2.41676.884 18.696 1005 CG SER 127 −3.383 76.445 17.753 1006 C SER 127 −0.99575.869 16.958 1007 O SER 127 −1.060 76.210 15.779 1008 N VAL 128 −0.89774.606 17.353 1009 CA VAL 128 −0.905 73.479 16.428 1010 CB VAL 128 0.50973.034 16.013 1011 CG1 VAL 128 0.411 71.890 15.016 1012 CG2 VAL 1281.264 74.191 15.398 1013 C VAL 128 −1.530 72.365 17.236 1014 O VAL 128−1.502 72.410 18.461 1015 N THR 129 −2.098 71.370 16.573 1016 CA THR 129−2.709 70.283 17.311 1017 CB THR 129 −4.133 70.650 17.778 1018 CG1 THR129 −4.050 71.546 18.890 1019 CG2 THR 129 −4.888 69.416 18.221 1020 CTHR 129 −2.765 69.008 16.507 1021 O THR 129 −3.714 68.757 15.766 1022 NLEU 130 −1.734 68.200 16.650 1023 CA LEU 130 −1.720 66.949 15.938 1024CB LEU 130 −0.330 66.339 15.974 1025 CG LEU 130 0.784 67.312 15.609 1026CD1 LEU 130 1.823 66.570 14.814 1027 CD2 LEU 130 0.236 68.475 14.8001028 C LEU 130 −2.696 66.068 16.657 1029 O LEU 130 −2.770 66.091 17.8931030 N THR 131 −3.460 65.308 15.892 1031 CA THR 131 −4.428 64.408 16.4691032 CB THR 131 −5.846 64.904 16.231 1033 OG1 THR 131 −5.850 66.33816.256 1034 CG2 THR 131 −6.772 64.379 17.316 1035 C THR 131 −4.19463.108 15.754 1036 O THR 131 −4.226 63.052 14.534 1037 N CYS 132 −3.92762.063 16.517 1038 CA CYS 132 −3.645 60.763 15.936 1039 C CYS 132 −4.90659.925 15.849 1040 O CYS 132 −5.303 59.271 16.809 1041 CB CYS 132 −2.58560.062 16.780 1042 SG CYS 132 −2.117 58.412 16.196 1043 N LEU 133 −5.52459.952 14.676 1044 CA LEU 133 −6.757 59.223 14.437 1045 CB LEU 133−7.383 59.673 13.120 1046 CG LEU 133 −8.722 60.397 13.275 1047 CD1 LEU133 −8.549 61.858 12.898 1048 CD2 LEU 133 −9.777 59.736 12.401 1049 CLEU 133 −6.579 57.724 14.413 1050 O LEU 133 −5.799 57.192 13.625 1051 NSER 134 −7.309 57.045 15.290 1052 CA SER 134 −7.253 55.596 15.342 1053CB SER 134 −6.187 55.099 16.316 1054 OG SER 134 −6.175 53.675 16.3351055 C SER 134 −8.575 54.994 15.746 1056 O SER 134 −9.367 55.589 16.4781057 N ASN 135 −8.799 53.793 15.245 1058 CA ASN 135 −9.999 53.047 15.5391059 CB ASN 135 −10.863 52.909 14.292 1060 CG ASN 135 −11.860 54.03914.163 1061 OD1 ASN 135 −12.186 54.480 13.058 1062 ND2 ASN 135 −12.35154.521 15.302 1063 C ASN 135 −9.442 51.720 15.970 1064 O ASN 135 −9.13150.848 15.161 1065 N ASP 136 −9.277 51.612 17.274 1066 CA ASP 136 −8.72850.438 17.919 1067 CB ASP 136 −7.239 50.272 17.601 1068 CG ASP 136−6.976 49.531 16.319 1069 OD1 ASP 136 −6.087 49.988 15.572 1070 OD2 ASP136 −7.632 48.497 16.067 1071 C ASP 136 −8.798 50.906 19.341 1072 O ASP136 −8.333 52.007 19.635 1073 N ILE 137 −9.386 50.138 20.237 1074 CA ILE137 −9.351 50.637 21.583 1075 CB ILE 137 −10.713 51.109 22.078 1076 CG2ILE 137 −10.604 51.547 23.539 1077 CG1 ILE 137 −11.122 52.328 21.2441078 CD1 ILE 137 −12.322 53.083 21.763 1079 C ILE 137 −8.682 49.65822.511 1080 O ILE 137 −9.017 48.475 22.593 1081 N GLY 138 −7.687 50.22223.177 1082 CA GLY 138 −6.805 49.532 24.088 1083 C GLY 138 −5.566 50.11223.436 1084 O GLY 138 −4.908 49.446 22.635 1085 N ALA 139 −5.269 51.37123.757 1086 CA ALA 139 −4.157 52.075 23.133 1087 CB ALA 139 −4.69753.336 22.471 1088 C ALA 139 −2.903 52.432 23.920 1089 O ALA 139 −2.88752.490 25.153 1090 N ASN 140 −1.853 52.682 23.143 1091 CA ASN 140 −0.54053.090 23.628 1092 CB ASN 140 0.376 51.888 23.874 1093 CG ASN 140 1.69652.291 24.505 1094 OD1 ASN 140 1.818 53.384 25.065 1095 ND2 ASN 1402.693 51.411 24.418 1096 C ASN 140 0.028 53.939 22.499 1097 O ASN 1400.842 53.480 21.696 1098 N ILE 141 −0.436 55.177 22.427 1099 CA ILE 1410.014 56.084 21.395 1100 CB ILE 141 −1.028 57.178 21.141 1101 CG2 ILE141 −0.363 58.390 20.520 1102 CG1 ILE 141 −2.136 56.646 20.232 1103 CD1ILE 141 −3.309 57.605 20.069 1104 C ILE 141 1.308 56.735 21.835 1105 OILE 141 1.489 57.027 23.014 1106 N GLN 142 2.207 56.953 20.881 1107 CAGLN 142 3.489 57.592 21.156 1108 CB GLN 142 4.615 56.558 21.158 1109 CGGLN 142 5.328 56.473 22.491 1110 CD GLN 142 6.569 55.613 22.445 1111 OE1GLN 142 7.498 55.879 21.678 1112 NE2 GLN 142 6.598 54.574 23.275 1113 CGLN 142 3.758 58.663 20.103 1114 O GLN 142 3.555 58.435 18.914 1115 NTRP 143 4.224 59.828 20.536 1116 CA TRP 143 4.470 60.916 19.607 1117 CBTRP 143 3.949 62.213 20.217 1118 CG TRP 143 2.460 62.318 20.138 1119 CD2TRP 143 1.676 62.566 18.961 1120 CE2 TRP 143 0.321 62.601 19.356 1121CE3 TRP 143 1.998 62.763 17.609 1122 CD1 TRP 143 1.568 62.211 21.1701123 NE1 TRP 143 0.280 62.382 20.709 1124 CZ2 TRP 143 −0.724 62.82718.444 1125 CZ3 TRP 143 0.957 62.988 16.701 1126 CH2 TRP 143 −0.38663.016 17.125 1127 C TRP 143 5.911 61.083 19.152 1128 O TRP 143 6.81161.354 19.945 1129 N LEU 144 6.114 60.934 17.850 1130 CA LEU 144 7.43961.063 17.266 1131 CB LEU 144 7.713 59.897 16.316 1132 CG LEU 144 7.55658.477 16.855 1133 CD1 LEU 144 7.691 58.465 18.373 1134 CD2 LEU 1446.207 57.938 16.426 1135 C LEU 144 7.642 62.370 16.514 1136 O LEU 1446.752 62.854 15.812 1137 N PHE 145 8.838 62.926 16.670 1138 CA PHE 1459.226 64.168 16.023 1139 CB PHE 145 9.501 65.239 17.087 1140 CG PHE 1459.914 66.584 16.534 1141 CD1 PHE 145 10.309 66.729 15.211 1142 CD2 PHE145 9.917 67.708 17.355 1143 CE1 PHE 145 10.703 67.964 14.716 1144 CE2PHE 145 10.311 68.953 16.864 1145 CZ PHE 145 10.704 69.078 15.541 1146 CPHE 145 10.500 63.837 15.258 1147 O PHE 145 11.448 63.305 15.830 1148 NASN 146 10.514 64.138 13.966 1149 CA ASN 146 11.679 63.871 13.131 1150CB ASN 146 12.812 64.833 13.480 1151 CG ASN 146 12.594 66.209 12.9001152 OD1 ASN 146 11.788 66.388 11.985 1153 ND2 ASN 146 13.308 67.19713.432 1154 C ASN 146 12.176 62.441 13.252 1155 O ASN 146 13.376 62.18513.158 1156 N SER 147 11.244 61.517 13.463 1157 CA SER 147 11.558 60.09513.583 1158 CB SER 147 12.364 59.632 12.365 1159 OG SER 147 12.42060.637 11.367 1160 C SER 147 12.286 59.695 14.868 1161 O SER 147 13.10058.773 14.883 1162 N GLN 148 11.988 60.399 15.948 1163 CA GLN 148 12.58160.103 17.236 1164 CB GLN 148 13.917 60.816 17.395 1165 CG GLN 14815.095 59.868 17.356 1166 CD GLN 148 16.418 60.587 17.467 1167 OE1 GLN148 16.492 61.802 17.289 1168 NE2 GLN 148 17.475 59.841 17.762 1169 CGLN 148 11.589 60.583 18.270 1170 O GLN 148 10.670 61.336 17.955 1171 NSER 149 11.766 60.147 19.505 1172 CA SER 149 10.845 60.512 20.565 1173CB SER 149 11.248 59.776 21.838 1174 OG SER 149 11.763 58.493 21.5161175 C SER 149 10.708 62.007 20.839 1176 O SER 149 11.694 62.692 21.1101177 N LEU 150 9.474 62.502 20.750 1178 CA LEU 150 9.181 63.909 21.0171179 CB LEU 150 7.720 64.216 20.666 1180 CG LEU 150 7.193 65.654 20.7531181 CD1 LEU 150 8.300 66.632 21.125 1182 CD2 LEU 150 6.604 66.02419.414 1183 C LEU 150 9.398 64.045 22.523 1184 O LEU 150 8.656 63.44823.300 1185 N GLN 151 10.394 64.823 22.949 1186 CA GLN 151 10.659 64.91624.383 1187 CB GLN 151 11.816 65.862 24.709 1188 CG GLN 151 12.40265.520 26.091 1189 CD GLN 151 13.150 66.658 26.756 1190 OE1 GLN 15113.451 67.675 26.131 1191 NE2 GLN 151 13.461 66.486 28.037 1192 C GLN151 9.496 65.275 25.278 1193 O GLN 151 9.531 64.984 26.476 1194 N LEU152 8.470 65.902 24.717 1195 CA LEU 152 7.314 66.266 25.522 1196 CB LEU152 6.735 65.023 26.196 1197 CG LEU 152 5.671 64.257 25.416 1198 CD1 LEU152 6.143 62.840 25.090 1199 CD2 LEU 152 4.411 64.221 26.252 1200 C LEU152 7.766 67.258 26.582 1201 O LEU 152 8.580 66.935 27.449 1202 N THR153 7.232 68.470 26.518 1203 CA THR 153 7.624 69.497 27.468 1204 CB THR153 8.691 70.399 26.854 1205 OG1 THR 153 8.067 71.578 26.333 1206 CG2THR 153 9.418 69.665 25.727 1207 C THR 153 6.479 70.371 27.986 1208 OTHR 153 5.306 70.042 27.820 1209 N GLU 154 6.841 71.493 28.604 1210 CAGLU 154 5.886 72.427 29.199 1211 CB GLU 154 6.654 73.480 30.006 1212 CGGLU 154 5.982 74.846 30.076 1213 CD GLU 154 6.956 75.961 30.427 1214 OE1GLU 154 7.347 76.063 31.613 1215 OE2 GLU 154 7.327 76.735 29.516 1216 CGLU 154 4.902 73.129 28.257 1217 O GLU 154 3.706 73.217 28.553 1218 NARG 155 5.401 73.643 27.138 1219 CA ARG 155 4.545 74.346 26.188 1220 CBARG 155 5.397 75.213 25.255 1221 CG ARG 155 5.844 74.515 23.977 1222 CDARG 155 7.111 75.149 23.420 1223 NE ARG 155 7.954 74.184 22.716 1224 CZARG 155 8.419 74.361 21.485 1225 NH1 ARG 155 8.110 75.461 20.815 1226NH2 ARG 155 9.189 73.439 20.923 1227 C ARG 155 3.658 73.412 25.368 1228O ARG 155 2.913 73.859 24.499 1229 N MET 156 3.744 72.114 25.634 1230 CAMET 156 2.920 71.147 24.922 1231 CB MET 156 3.751 69.939 24.494 1232 CGMET 156 5.212 70.243 24.260 1233 SD MET 156 5.998 68.984 23.234 1234 CEMET 156 7.453 69.872 22.674 1235 C MET 156 1.787 70.698 25.838 1236 OMET 156 1.860 70.866 27.054 1237 N THR 157 0.743 70.130 25.246 1238 CATHR 157 −0.422 69.670 25.992 1239 CB THR 157 −1.486 70.768 26.107 1240OG1 THR 157 −0.956 71.881 26.836 1241 CG2 THR 157 −2.726 70.232 26.8041242 C THR 157 −1.063 68.546 25.220 1243 O THR 157 −1.376 68.717 24.0431244 N LEU 158 −1.273 67.402 25.856 1245 CA LEU 158 −1.908 66.321 25.1301246 CB LEU 158 −0.852 65.402 24.537 1247 CG LEU 158 0.097 64.741 25.5091248 CD1 LEU 158 −0.326 63.307 25.688 1249 CD2 LEU 158 1.497 64.80024.958 1250 C LEU 158 −2.908 65.541 25.959 1251 O LEU 158 −2.641 65.18427.100 1252 N SER 159 −4.065 65.279 25.359 1253 CA SER 159 −5.132 64.57526.043 1254 CB SER 159 −6.209 65.570 26.443 1255 OG SER 159 −6.85366.060 25.283 1256 C SER 159 −5.787 63.433 25.286 1257 O SER 159 −5.20262.853 24.375 1258 N GLN 160 −7.039 63.172 25.664 1259 CA GLN 160 −7.83462.080 25.131 1260 CB GLN 160 −8.685 62.520 23.947 1261 CG GLN 160−10.139 62.644 24.420 1262 CD GLN 160 −10.994 63.577 23.594 1263 OE1 GLN160 −10.635 63.951 22.473 1264 NE2 GLN 160 −12.144 63.958 24.146 1265 CGLN 160 −6.862 60.971 24.809 1266 O GLN 160 −6.550 60.652 23.668 1267 NASN 161 −6.364 60.435 25.915 1268 CA ASN 161 −5.387 59.375 25.978 1269CB ASN 161 −6.082 58.021 25.966 1270 CG ASN 161 −6.462 57.569 27.3621271 OD1 ASN 161 −7.482 56.908 27.564 1272 ND2 ASN 161 −5.636 57.93228.341 1273 C ASN 161 −4.353 59.476 24.896 1274 O ASN 161 −4.311 58.66723.983 1275 N ASN 162 −3.517 60.499 25.017 1276 CA ASN 162 −2.441 60.75024.069 1277 CB ASN 162 −1.438 59.590 24.114 1278 CG ASN 162 −0.55959.621 25.344 1279 OD1 ASN 162 −0.539 60.594 26.090 1280 ND2 ASN 1620.183 58.543 25.558 1281 C ASN 162 −2.891 60.969 22.614 1282 O ASN 162−2.053 61.185 21.739 1283 N SER 163 −4.196 60.921 22.350 1284 CA SER 163−4.695 61.095 20.986 1285 CB SER 163 −6.208 60.892 20.925 1286 OG SER163 −6.539 59.620 20.402 1287 C SER 163 −4.387 62.463 20.432 1288 O SER163 −3.653 62.605 19.465 1289 N ILE 164 −4.966 63.473 21.056 1290 CA ILE164 −4.785 64.846 20.622 1291 CB ILE 164 −6.029 65.666 20.968 1292 CG2ILE 164 −6.030 66.958 20.176 1293 CG1 ILE 164 −7.279 64.813 20.712 1294CD1 ILE 164 −8.599 65.559 20.823 1295 C ILE 164 −3.566 65.502 21.2521296 O ILE 164 −3.420 65.516 22.470 1297 N LEU 165 −2.694 66.050 20.4191298 CA LEU 165 −1.500 66.709 20.912 1299 CB LEU 165 −0.256 66.03720.346 1300 CG LEU 165 0.980 66.933 20.245 1301 CD1 LEU 165 1.169 67.74121.529 1302 CD2 LEU 165 2.193 66.057 19.991 1303 C LEU 165 −1.540 68.16320.478 1304 O LEU 165 −1.692 68.459 19.290 1305 N ARG 166 −1.373 69.06421.444 1306 CA ARG 166 −1.420 70.496 21.178 1307 CB ARG 166 −2.68871.081 21.810 1308 CG ARG 166 −2.621 72.557 22.164 1309 CD ARG 166−4.021 73.114 22.446 1310 NE ARG 166 −4.466 72.851 23.817 1311 CZ ARG166 −5.741 72.717 24.186 1312 NH1 ARG 166 −6.712 72.804 23.284 1313 NH2ARG 166 −6.048 72.481 25.456 1314 C ARG 166 −0.197 71.254 21.675 1315 OARG 166 0.006 71.408 22.874 1316 N ILE 167 0.609 71.732 20.738 1317 CAILE 167 1.802 72.489 21.069 1318 CB ILE 167 2.904 72.257 20.045 1319 CG2ILE 167 4.048 73.224 20.294 1320 CG1 ILE 167 3.366 70.799 20.118 1321CD1 ILE 167 3.852 70.228 18.792 1322 C ILE 167 1.426 73.952 21.037 1323O ILE 167 0.783 74.413 20.089 1324 N ASP 168 1.836 74.682 22.069 1325 CAASP 168 1.534 76.102 22.179 1326 CB ASP 168 0.011 76.281 22.245 1327 CGASP 168 −0.406 77.633 22.778 1328 OD1 ASP 168 0.157 78.081 23.799 1329OD2 ASP 168 −1.311 78.246 22.175 1330 C ASP 168 2.177 76.676 23.442 1331O ASP 168 1.923 76.196 24.547 1332 N PRO 169 3.028 77.710 23.301 1333 CDPRO 169 3.701 78.273 24.480 1334 CA PRO 169 3.412 78.434 22.082 1335 CBPRO 169 4.070 79.694 22.625 1336 CG PRO 169 4.699 79.233 23.880 1337 CPRO 169 4.383 77.652 21.201 1338 O PRO 169 5.289 76.989 21.704 1339 NILE 170 4.200 77.737 19.886 1340 CA ILE 170 5.091 77.035 18.979 1341 CBILE 170 4.441 76.816 17.612 1342 CG2 ILE 170 3.976 75.374 17.482 1343CG1 ILE 170 3.279 77.789 17.443 1344 CD1 ILE 170 2.248 77.323 16.4731345 C ILE 170 6.349 77.869 18.798 1346 O ILE 170 6.329 79.086 18.9901347 N LYS 171 7.444 77.211 18.441 1348 CA LYS 171 8.713 77.895 18.2281349 CB LYS 171 9.517 77.941 19.533 1350 CG LYS 171 10.508 76.802 19.7351351 CD LYS 171 10.927 76.707 21.200 1352 CE LYS 171 12.407 76.39021.343 1353 NZ LYS 171 13.244 77.619 21.403 1354 C LYS 171 9.485 77.17217.136 1355 O LYS 171 9.442 75.942 17.050 1356 N ARG 172 10.189 77.93616.306 1357 CA ARG 172 10.934 77.361 15.198 1358 CB ARG 172 12.03278.314 14.713 1359 CG ARG 172 12.759 79.107 15.786 1360 CD ARG 17213.763 80.063 15.135 1361 NE ARG 172 14.959 80.279 15.947 1362 CZ ARG172 15.943 81.113 15.623 1363 NH1 ARG 172 15.877 81.816 14.496 1364 NH2ARG 172 16.993 81.249 16.426 1365 C ARG 172 11.527 75.994 15.490 1366 OARG 172 11.560 75.143 14.607 1367 N GLU 173 11.989 75.773 16.719 1368 CAGLU 173 12.564 74.478 17.077 1369 CB GLU 173 12.691 74.334 18.601 1370CG GLU 173 13.323 73.012 19.051 1371 CD GLU 173 13.568 72.938 20.5511372 OE1 GLU 173 12.746 73.481 21.323 1373 OE2 GLU 173 14.584 72.33120.956 1374 C GLU 173 11.638 73.397 16.535 1375 O GLU 173 12.091 72.37116.020 1376 N ASP 174 10.339 73.660 16.637 1377 CA ASP 174 9.310 72.74416.174 1378 CB ASP 174 7.945 73.248 16.618 1379 CG ASP 174 7.884 73.49718.103 1380 OD1 ASP 174 7.729 74.670 18.500 1381 OD2 ASP 174 7.99572.518 18.873 1382 C ASP 174 9.316 72.553 14.661 1383 O ASP 174 8.40771.941 14.106 1384 N ALA 175 10.339 73.081 13.997 1385 CA ALA 175 10.47072.948 12.552 1386 CB ALA 175 11.540 73.900 12.034 1387 C ALA 175 10.85971.513 12.233 1388 O ALA 175 12.046 71.176 12.229 1389 N GLY 176 9.86070.673 11.974 1390 CA GLY 176 10.121 69.277 11.662 1391 C GLY 176 8.87468.493 11.282 1392 O GLY 176 7.785 69.061 11.203 1393 N GLU 177 9.02667.190 11.045 1394 CA GLU 177 7.899 66.340 10.663 1395 CB GLU 177 8.26465.482 9.443 1396 CG GLU 177 9.615 64.773 9.528 1397 CD GLU 177 9.85563.828 8.358 1398 OE1 GLU 177 9.770 62.594 8.555 1399 OE2 GLU 177 10.12964.320 7.241 1400 C GLU 177 7.442 65.449 11.819 1401 O GLU 177 8.19564.618 12.329 1402 N TYR 178 6.190 65.623 12.217 1403 CA TYR 178 5.63764.882 13.336 1404 CB TYR 178 4.768 65.822 14.172 1405 CG TYR 178 5.52667.022 14.730 1406 CD1 TYR 178 5.133 67.625 15.919 1407 CE1 TYR 1785.844 68.698 16.453 1408 CD2 TYR 178 6.655 67.535 14.084 1409 CE2 TYR178 7.368 68.607 14.611 1410 CZ TYR 178 6.958 69.182 15.796 1411 OH TYR178 7.672 70.227 16.339 1412 C TYR 178 4.858 63.649 12.913 1413 O TYR178 4.119 63.659 11.928 1414 N GLN 179 5.026 62.585 13.688 1415 CA GLN179 4.394 61.299 13.409 1416 CB GLN 179 5.441 60.371 12.787 1417 CG GLN179 4.926 59.259 11.903 1418 CD GLN 179 6.046 58.634 11.083 1419 OE1 GLN179 6.387 57.467 11.257 1420 NE2 GLN 179 6.628 59.417 10.189 1421 C GLN179 3.853 60.662 14.689 1422 O GLN 179 4.525 60.665 15.724 1423 N CYS180 2.642 60.116 14.620 1424 CA CYS 180 2.051 59.460 15.778 1425 C CYS180 2.236 57.959 15.597 1426 O CYS 180 2.267 57.468 14.472 1427 CB CYS180 0.568 59.819 15.907 1428 SG CYS 180 −0.533 58.739 14.967 1429 N GLU181 2.382 57.235 16.703 1430 CA GLU 181 2.587 55.789 16.649 1431 CB GLU181 4.067 55.465 16.818 1432 CG GLU 181 4.350 54.006 17.128 1433 CD GLU181 5.835 53.725 17.242 1434 OE1 GLU 181 6.532 54.499 17.932 1435 OE2GLU 181 6.309 52.736 16.639 1436 C GLU 181 1.791 55.018 17.691 1437 OGLU 181 1.810 55.349 18.879 1438 N ILE 182 1.110 53.974 17.231 1439 CAILE 182 0.294 53.141 18.099 1440 CB ILE 182 −0.994 52.683 17.391 1441CG2 ILE 182 −1.620 51.545 18.166 1442 CG1 ILE 182 −1.999 53.830 17.3011443 CD1 ILE 182 −3.384 53.384 16.842 1444 C ILE 182 1.038 51.886 18.5281445 O ILE 182 1.702 51.245 17.714 1446 N SER 183 0.912 51.541 19.8081447 CA SER 183 1.535 50.346 20.359 1448 CB SER 183 2.515 50.710 21.4801449 OG SER 183 2.933 52.062 21.383 1450 C SER 183 0.440 49.430 20.8961451 O SER 183 −0.691 49.849 21.122 1452 N ASN 184 0.809 48.177 21.0881453 CA ASN 184 −0.033 47.080 21.577 1454 CB ASN 184 −0.421 46.22920.360 1455 CG ASN 184 −1.611 45.318 20.594 1456 OD1 ASN 184 −1.45844.113 20.810 1457 ND2 ASN 184 −2.806 45.880 20.508 1458 C ASN 184 1.17146.459 22.226 1459 O ASN 184 2.143 47.174 22.463 1460 N PRO 185 1.10345.201 22.682 1461 CD PRO 185 0.255 44.039 22.962 1462 CA PRO 185 2.46744.997 23.142 1463 CB PRO 185 2.403 43.689 23.928 1464 CG PRO 185 0.93943.454 24.169 1465 C PRO 185 3.056 44.823 21.727 1466 O PRO 185 2.36944.356 20.813 1467 N VAL 186 4.290 45.259 21.548 1468 CA VAL 186 4.99745.228 20.277 1469 CB VAL 186 6.459 44.866 20.580 1470 CG1 VAL 186 7.33645.068 19.361 1471 CG2 VAL 186 6.944 45.777 21.719 1472 C VAL 186 4.42644.464 19.058 1473 O VAL 186 4.903 43.395 18.659 1474 N SER 187 3.39745.096 18.488 1475 CA SER 187 2.633 44.712 17.294 1476 CB SER 187 1.40843.872 17.660 1477 OG SER 187 1.662 42.485 17.534 1478 C SER 187 2.17246.120 16.923 1479 O SER 187 0.999 46.463 17.052 1480 N VAL 188 3.12146.935 16.481 1481 CA VAL 188 2.869 48.337 16.180 1482 CB VAL 188 4.02449.165 16.722 1483 CG1 VAL 188 3.780 49.508 18.179 1484 CG2 VAL 1885.312 48.367 16.589 1485 C VAL 188 2.657 48.746 14.735 1486 O VAL 1882.845 47.956 13.819 1487 N ARG 189 2.270 50.005 14.553 1488 CA ARG 1892.046 50.590 13.235 1489 CB ARG 189 0.689 50.161 12.672 1490 CG ARG 1890.730 48.784 12.041 1491 CD ARG 189 −0.167 48.650 10.828 1492 NE ARG 189−0.505 47.248 10.598 1493 CZ ARG 189 −1.608 46.826 9.990 1494 NH1 ARG189 −2.491 47.701 9.525 1495 NH2 ARG 189 −1.826 45.525 9.846 1496 C ARG189 2.118 52.109 13.353 1497 O ARG 189 1.350 52.721 14.099 1498 N ARG190 3.053 52.709 12.620 1499 CA ARG 190 3.254 54.155 12.646 1500 CB ARG190 4.685 54.490 12.218 1501 CG ARG 190 5.757 53.710 12.980 1502 CD ARG190 7.160 54.199 12.633 1503 NE ARG 190 8.150 53.848 13.652 1504 CZ ARG190 9.397 54.317 13.683 1505 NH1 ARG 190 9.826 55.146 12.741 1506 NH2ARG 190 10.227 53.943 14.651 1507 C ARG 190 2.264 54.889 11.756 1508 OARG 190 1.606 54.289 10.919 1509 N SER 191 2.167 56.196 11.944 1510 CASER 191 1.246 57.011 11.168 1511 CB SER 191 0.706 58.132 12.037 1512 OGSER 191 1.788 58.879 12.565 1513 C SER 191 1.967 57.616 9.979 1514 O SER191 3.117 57.271 9.707 1515 N ASN 192 1.286 58.523 9.277 1516 CA ASN 1921.864 59.195 8.118 1517 CB ASN 192 0.854 60.116 7.402 1518 CG ASN 192−0.575 59.983 7.918 1519 OD1 ASN 192 −1.419 60.832 7.627 1520 ND2 ASN192 −0.857 58.928 8.672 1521 C ASN 192 3.041 60.027 8.612 1522 O ASN 1923.726 59.632 9.549 1523 N SER 193 3.275 61.186 8.009 1524 CA SER 1934.403 62.004 8.433 1525 CB SER 193 5.637 61.641 7.603 1526 OG SER 1936.457 60.688 8.255 1527 C SER 193 4.153 63.497 8.314 1528 O SER 1934.996 64.218 7.789 1529 N ILE 194 3.016 63.975 8.802 1530 CA ILE 1942.726 65.401 8.699 1531 CB ILE 194 1.601 65.832 9.657 1532 CG2 ILE 1941.812 67.272 10.111 1533 CG1 ILE 194 0.261 65.769 8.929 1534 CD1 ILE 194−0.547 64.518 9.213 1535 C ILE 194 3.957 66.242 8.997 1536 O ILE 1944.530 66.169 10.084 1537 N LYS 195 4.372 67.028 8.015 1538 CA LYS 1955.520 67.887 8.200 1539 CB LYS 195 6.298 68.048 6.899 1540 CG LYS 1957.683 68.627 7.083 1541 CD LYS 195 8.725 67.751 6.400 1542 CE LYS 1959.479 68.524 5.328 1543 NZ LYS 195 9.757 69.919 5.768 1544 C LYS 1954.949 69.216 8.615 1545 O LYS 195 3.903 69.632 8.130 1546 N LEU 1965.619 69.879 9.534 1547 CA LEU 196 5.116 71.148 9.965 1548 CB LEU 1964.595 71.096 11.396 1549 CG LEU 196 3.220 71.740 11.531 1550 CD1 LEU 1962.161 70.672 11.305 1551 CD2 LEU 196 3.070 72.376 12.901 1552 C LEU 1966.164 72.183 9.878 1553 O LEU 196 7.228 72.072 10.500 1554 N ASP 1975.898 73.178 9.059 1555 CA ASP 197 6.837 74.229 9.021 1556 CB ASP 1977.709 74.165 7.787 1557 CG ASP 197 8.895 73.228 8.028 1558 OD1 ASP 1979.252 73.021 9.215 1559 OD2 ASP 197 9.458 72.713 7.054 1560 C ASP 1976.273 75.555 9.384 1561 O ASP 197 5.109 75.907 9.210 1562 N ILE 1987.220 76.250 9.960 1563 CA ILE 198 7.038 77.458 10.603 1564 CB ILE 1987.825 77.209 11.864 1565 CG2 ILE 198 7.563 78.212 12.916 1566 CG1 ILE198 7.724 75.715 12.220 1567 CD1 ILE 198 7.332 75.402 13.587 1568 C ILE198 7.399 78.768 10.077 1569 O ILE 198 8.531 79.018 9.594 1570 N ILE 1996.432 79.670 10.121 1571 CA ILE 199 6.860 80.919 9.867 1572 CB ILE 1996.413 81.508 8.557 1573 CG2 ILE 199 7.302 82.734 8.216 1574 CG1 ILE 1996.593 80.448 7.458 1575 CD1 ILE 199 7.976 80.448 6.836 1576 C ILE 1996.456 81.727 11.001 1577 O ILE 199 5.422 81.545 11.660 1578 N PHE 2007.234 82.727 11.168 1579 CA PHE 200 7.084 83.578 12.230 1580 CB PHE 2008.459 83.630 12.866 1581 CG PHE 200 9.604 83.348 11.902 1582 CD1 PHE 20010.400 84.395 11.482 1583 CD2 PHE 200 9.830 82.079 11.360 1584 CE1 PHE200 11.394 84.220 10.540 1585 CE2 PHE 200 10.842 81.888 10.396 1586 CZPHE 200 11.621 82.969 9.989 1587 C PHE 200 6.534 84.873 11.715 1588 OPHE 200 6.814 85.256 10.577 1589 N ASP 201 5.740 85.535 12.552 1590 CAASP 201 5.155 86.767 12.139 1591 CB ASP 201 3.892 87.051 12.951 1592 CGASP 201 2.858 87.774 12.141 1593 OD1 ASP 201 2.902 87.651 10.902 1594OD2 ASP 201 2.010 88.465 12.737 1595 C ASP 201 6.087 87.950 12.118 1596O ASP 201 6.272 88.541 11.054 1597 N PRO 202 6.687 88.326 13.264 1598 CDPRO 202 6.585 87.855 14.653 1599 CA PRO 202 7.577 89.491 13.127 1600 CBPRO 202 7.868 89.922 14.573 1601 CG PRO 202 7.024 89.062 15.456 1602 CPRO 202 8.890 89.293 12.335 1603 O PRO 202 9.194 88.217 11.844 1604 NSER 203 9.650 90.380 12.225 1605 CA SER 203 10.953 90.378 11.527 1606 CBSER 203 10.734 90.705 10.057 1607 OG SER 203 11.645 90.034 9.214 1608 CSER 203 11.923 91.387 12.150 1609 O SER 203 11.472 92.453 12.608 1610 OTSER 203 13.127 91.080 12.183 1611 C1 NAG 337 −9.469 33.186 42.953 1612C2 NAG 337 −8.576 34.420 43.270 1613 N2 NAG 337 −7.690 34.719 42.1481614 C7 NAG 337 −6.368 34.889 42.274 1615 O7 NAG 337 −5.755 34.78843.335 1616 C8 NAG 337 −5.619 35.210 40.989 1617 C3 NAG 337 −7.80034.291 44.601 1618 O3 NAG 337 −7.298 35.563 44.985 1619 C4 NAG 337−8.703 33.767 45.709 1620 O4 NAG 337 −7.958 33.573 46.905 1621 C5 NAG337 −9.300 32.455 45.239 1622 O5 NAG 337 −10.171 32.702 44.114 1623 C6NAG 337 −10.115 31.763 46.313 1624 O6 NAG 337 −9.595 30.471 46.594 1625C1 NAG 355 −4.287 13.449 24.968 1626 C2 NAG 355 −4.296 14.880 24.4171627 N2 NAG 355 −5.400 15.604 25.013 1628 C7 NAG 355 −5.298 16.91225.215 1629 O7 NAG 355 −4.280 17.541 24.943 1630 C8 NAG 355 −6.50717.605 25.825 1631 C3 NAG 355 −4.464 14.904 22.887 1632 O3 NAG 355−4.235 16.218 22.400 1633 C4 NAG 355 −3.494 13.925 22.223 1634 O4 NAG355 −3.669 13.927 20.814 1635 C5 NAG 355 −3.783 12.549 22.796 1636 O5NAG 355 −3.459 12.560 24.196 1637 C6 NAG 355 −2.985 11.426 22.155 1638O6 NAG 355 −3.099 10.223 22.904 1639 C1 NAG 370 6.875 20.681 28.445 1640C2 NAG 370 8.262 21.265 28.392 1641 N2 NAG 370 8.681 21.759 29.689 1642C7 NAG 370 9.976 21.812 29.982 1643 O7 NAG 370 10.850 21.497 29.175 1644C8 NAG 370 10.344 22.309 31.367 1645 C3 NAG 370 8.191 22.354 27.338 1646O3 NAG 370 9.470 22.953 27.184 1647 C4 NAG 370 7.718 21.741 25.991 1648O4 NAG 370 7.191 22.783 25.156 1649 C5 NAG 370 6.617 20.651 26.078 1650O5 NAG 370 6.692 19.853 27.296 1651 C6 NAG 370 6.739 19.703 24.903 1652O6 NAG 370 6.222 20.290 23.714 1653 C1 NAG 371 7.907 23.026 24.005 1654C2 NAG 371 7.150 23.963 23.089 1655 N2 NAG 371 5.717 23.735 22.982 1656C7 NAG 371 5.172 22.761 22.258 1657 O7 NAG 371 5.822 21.934 21.619 1658C8 NAG 371 3.646 22.729 22.275 1659 C3 NAG 371 7.904 23.921 21.782 1660O3 NAG 371 7.174 24.587 20.756 1661 C4 NAG 371 9.179 24.679 22.101 1662O4 NAG 371 10.034 24.722 20.972 1663 C5 NAG 371 9.963 24.103 23.299 1664O5 NAG 371 9.119 23.677 24.394 1665 C6 NAG 371 10.846 25.160 23.903 1666O6 NAG 371 11.950 25.428 23.072 1667 C1 MAN 372 10.464 25.992 20.6791668 C2 MAN 372 12.019 26.016 20.807 1669 O2 MAN 372 12.611 24.88120.198 1670 C3 MAN 372 12.612 27.284 20.168 1671 O3 MAN 372 14.02327.153 20.050 1672 C4 MAN 372 12.025 27.564 18.780 1673 O4 MAN 37212.409 28.867 18.345 1674 C5 MAN 372 10.503 27.484 18.806 1675 O5 MAN372 10.091 26.245 19.350 1676 C6 MAN 372 9.983 27.420 17.396 1677 O6 MAN372 10.129 26.089 16.855 1678 C1 NAG 419 −3.760 78.706 7.779 1679 C2 NAG419 −4.885 78.830 6.751 1680 N2 NAG 419 −4.899 77.687 5.857 1681 C7 NAG419 −5.923 76.838 5.874 1682 O7 NAG 419 −6.881 76.962 6.636 1683 C8 NAG419 −5.855 75.676 4.897 1684 C3 NAG 419 −4.660 80.124 5.960 1685 O3 NAG419 −5.734 80.323 5.049 1686 C4 NAG 419 −4.554 81.334 6.909 1687 O4 NAG419 −4.151 82.483 6.172 1688 C5 NAG 419 −3.546 81.075 8.051 1689 O5 NAG419 −3.815 79.806 8.695 1690 C6 NAG 419 −3.619 82.140 9.131 1691 O6 NAG419 −2.839 83.275 8.790

[0141] TABLE 7 Coordinate set of the CC′ loop of D1 of murine CEACAM1a(partial sequence of #5, corresponding to amino acid positions 35through 45 (atoms positions 26 through 343) ANum AType RType RNum X Y Z264 N LYS 35 −9.666 26.313 34.082 265 CA LYS 35 −9.714 27.692 33.635 266CB LYS 35 −10.484 27.750 32.307 267 CG LYS 35 −10.801 29.140 31.738 268CD LYS 35 −11.408 29.009 30.325 269 CE LYS 35 −11.841 30.347 29.722 270NZ LYS 35 −12.528 30.158 28.405 271 C LYS 35 −10.412 28.539 34.692 272 OLYS 35 −11.465 28.161 35.194 273 N GLY 36 −9.800 29.656 35.067 274 CAGLY 36 −10.439 30.553 36.013 275 C GLY 36 −10.360 30.443 37.525 276 OGLY 36 −11.214 31.020 38.198 277 N ASN 37 −9.385 29.730 38.082 278 CAASN 37 −9.277 29.656 39.544 279 GB ASN 37 −9.365 31.100 40.114 280 CGASN 37 −9.477 31.164 41.641 281 OD1 ASN 37 −10.210 30.393 42.258 282 ND2ASN 37 −8.770 32.120 42.251 283 C ASN 37 −10.311 28.710 40.190 284 O ASN37 −10.123 28.267 41.322 285 N THR 38 −11.391 28.380 39.484 286 CA THR38 −12.386 27.470 40.055 287 CB THR 38 −13.700 27.427 39.235 288 OG1 THR38 −13.450 27.862 37.895 289 CG2 THR 38 −14.762 28.307 39.873 290 C THR38 −11.839 26.046 40.086 291 O THR 38 −11.673 25.421 39.040 292 N THR 39−11.557 25.536 41.282 293 CA THR 39 −11.052 24.170 41.439 294 CB THR 39−10.387 23.980 42.832 295 OG1 THR 39 −10.417 22.598 43.203 296 CG2 THR39 −11.115 24.796 43.891 297 C THR 39 −12.252 23.233 41.305 298 O THR 39−12.347 22.204 41.970 299 N ALA 40 −13.164 23.603 40.413 300 CA ALA 40−14.382 22.841 40.199 301 CB ALA 40 −15.580 23.771 40.320 302 C ALA 40−14.476 22.058 38.895 344 C ILE 45 −9.194 19.372 30.284 345 O ILE 45−9.182 18.856 29.167 303 O ALA 40 −14.212 22.578 37.809 304 N ILE 41−14.885 20.799 39.027 305 CA ILE 41 −15.070 19.895 37.898 306 GB ILE 41−15.826 18.634 38.337 307 CG2 ILE 41 −15.263 17.415 37.631 308 CG1 ILE41 −15.727 18.477 39.856 309 CD1 ILE 41 −17.058 18.210 40.531 310 C ILE41 −15.897 20.607 36.837 311 O ILE 41 −15.950 20.193 35.677 312 N ASP 42−16.558 21.675 37.268 313 CA ASP 42 −17.380 22.496 36.401 314 CB ASP 42−17.748 23.795 37.127 315 CG ASP 42 −18.993 24.455 36.566 316 OD1 ASP 42−18.907 25.110 35.506 317 OD2 ASP 42 −20.064 24.324 37.194 318 C ASP 42−16.540 22.825 35.182 319 O ASP 42 −17.032 22.831 34.053 320 N LYS 43−15.257 23.071 35.430 321 CA LYS 43 −14.335 23.446 34.372 322 CB LYS 43−13.943 24.914 34.554 323 CG LYS 43 −15.024 25.780 35.195 324 CD LYS 43−15.987 26.329 34.143 325 CE LYS 43 −16.654 27.625 34.597 326 NZ LYS 43−17.005 28.511 33.447 327 C LYS 43 −13.066 22.607 34.257 328 O LYS 43−11.965 23.130 34.423 329 N GLU 44 −13.205 21.319 33.959 330 CA GLU 44−12.030 20.466 33.812 331 CB GLU 44 −12.250 19.092 34.441 332 CG GLU 44−11.089 18.143 34.173 333 CD GLU 44 −11.047 16.967 35.126 334 OE1 GLU 44−10.883 17.186 36.346 335 OE2 GLU 44 −11.174 15.819 34.648 336 C GLU 44−11.701 20.275 32.347 337 O GLU 44 −12.521 19.755 31.591 338 N ILE 45−10.501 20.688 31.949 339 CA ILE 45 −10.088 20.545 30.562 340 CB ILE 45−9.347 21.766 30.035 341 CG2 ILE 45 −9.435 21.761 28.517 342 CG1 ILE 45−9.902 23.040 30.678 343 CD1 ILE 45 −9.672 24.296 29.865

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What is claimed is:
 1. A method for screening and selecting a candidatesubstance for sufficient binding and/or that inhibits binding to aCEACAM1 or a structurally related CEA family member molecule comprising:preparing a soluble CEACAM1antigen comprising a functional bindingdomain, D1, having a protruding, convoluted CC′ loop amino acid sequenceof K G E R V D G N R Q a C-terminal domain, D4, having an elongated CDloop, and a flexible linker connecting D1 to D4, to provide a targetmolecule; preparing a control sample comprising the target molecule anda monoclonal antibody or other antibody-like functionally equivalentmolecules having specific binding affinity for the CC′ loop or thatcompetes for binding to serial CC′ loop, and preparing a test samplecomprising the target molecule and a candidate substance; incubating thecontrol sample and the test sample for a period of time and underappropriate conditions to permit binding to the target molecule in thecontrol sample; and comparing the amount of bound target molecule in thecontrol sample to the amount of candidate agent bound to the targetmolecule in the test sample, wherein a candidate agent having at least40% the amount of bound candidate agent to target molecule compared tothe amount of bound target molecule in the control sample is selected ashaving sufficient binding/inhibiting activity.
 2. The method of claim 1wherein D1 of the CEACAM1 antigen farther comprises a first and a secondanti-parallel beta-sheet connected to one another by a salt bridge. 3.The method of claim 1 wherein the biological activity inhibited is celladhesion, tumor metastasis, angiogenesis, virus binding and/orinfection, or bacterial or infection and/or infection.
 4. The method ofclaim 1 wherein the candidtaet molecule binds or inhibits binding to aligand comprising homophilic binding domain of CEACAM1, MHV viral spikeglycoprotein, Neisseria, or Hemophilus bacteria.
 5. The method of claim1 wherein the target molecule comprises a cell surface receptor.
 6. Themethod of claim 5 wherein the target molecule comprises a cell surfaceprotein on an epithelial cell, a leukocyte, an endothelial cell, or aplacental cell.
 7. The method of claim 1 wherein the selected candidatesubstance inhibits virus binding.
 8. The method of claim 4 wherein theselected candidate substance inhibits binding of a pathogenic strain ofbacteria of Neisseria or Hemophilus.
 9. The method of claim 8 whereinthe pathogenic strain is a Hemophilus strain.
 10. The method of claim 1wherein the selected candidate substance is capable of blockingcell-mediated immune responses.
 11. The method of claim 1 wherein theselected candidate substance provides a bacterial inhibiting activity.12. The method of claim 11 wherein the selected candidate substanceprovides a treatment for bacterial infection.
 13. The method of claim 10wherein the selected candidate substance provides a treatment fordiarrhea.
 14. The method of claim 10 wherein the selected candidatesubstance provides a treatment for hepatitis.
 15. A soluble peptide inthe CEA family comprising: a hydrophobic core structure; a functionalbinding domain D1 having a convoluted and protruding CC′ loop structure;and a carboxy terminal D4 containing an elongated CD loop.
 16. Thesoluble CEA family peptide of claim 15 further defined as having an A-A′kink comprising a cis-proline amino acid residue.
 17. The soluble CEAfamily peptide of claim 15 further comprising a detectable molecular tagmolecule.
 18. The soluble CEA family peptide of claim 15 further definedas comprising an amino acid sequence of SEQ ID NO:
 1. 19. The solubleCEA family protein of claim 15 further defined as comprising an aminoacid sequence of SEQ ID NO:
 2. 20. The soluble CEA family protein ofclaim 15 further defined as comprising an amino acid sequence of SEQ IDNO:
 3. 21. The soluble CEA family protein of claim 15 further defined asa cellular receptor for a coronavirus.
 22. A pharmaceutical formulationcomprising the peptide of claim 14 in a pharmaceutically acceptableexcipient.
 23. The pharmaceutical formulation of claim 22 furtherdefined as an antiviral agent.
 24. An antiviral agent comprising amolecule capable of binding with high affinity and under stringentconditions to a target antigen molecule having: a virus binding domain,D1, having a protruding, convoluted CC′ loop, and an A-A′ kink; aC-terminal domain, D4, having an elongated CD loop, and a flexiblelinker connecting D1 to D4.
 25. The antiviral agent of claim 24 whereinthe anti-viral agent is further defined as binding to the target antigenmolecule with an affinity of about 10⁴ to about 10¹⁰.
 26. A method forselecting a pharmaceutical candidate compound comprising; a)immobilizing a CEACAM1 molecule having a sequence of SEQ ID NO. 1 or SEQID NO. 2 to a surface of a microtitor well having a plurality of wells;b) adding an aliquot of a molecular library containing a number oflibrary members; c) adding cells having a detectable label that expressa ligand for CEACAM1 to the wells; d) incubating the well comoponentsfor a period sufficient to permit cells to bind immobilized CEACAM1; ande) washing the wells to remove non-adherant cells; wherein bound labeledcells identify the library members that are selected as a pharmaceuticalcandidate.
 27. The method of claim 26 wherein the cells are labeled withCr51 or a flourescent dye.